Source code for bokeh.models.tools
#-----------------------------------------------------------------------------
# Copyright (c) 2012 - 2022, Anaconda, Inc., and Bokeh Contributors.
# All rights reserved.
#
# The full license is in the file LICENSE.txt, distributed with this software.
#-----------------------------------------------------------------------------
''' Bokeh comes with a number of interactive tools.
There are five types of tool interactions:
.. hlist::
:columns: 5
* Pan/Drag
* Click/Tap
* Scroll/Pinch
* Actions
* Inspectors
For the first three comprise the category of gesture tools, and only
one tool for each gesture can be active at any given time. The active
tool is indicated on the toolbar by a highlight next to the tool.
Actions are immediate or modal operations that are only activated when
their button in the toolbar is pressed. Inspectors are passive tools that
merely report information or annotate the plot in some way, and may
always be active regardless of what other tools are currently active.
'''
#-----------------------------------------------------------------------------
# Boilerplate
#-----------------------------------------------------------------------------
from __future__ import annotations
import logging # isort:skip
log = logging.getLogger(__name__)
#-----------------------------------------------------------------------------
# Imports
#-----------------------------------------------------------------------------
# Standard library imports
import difflib
import typing as tp
from typing import Literal
# Bokeh imports
from ..core.enums import (
Anchor,
Dimension,
Dimensions,
SelectionMode,
ToolIcon,
TooltipAttachment,
TooltipFieldFormatter,
)
from ..core.has_props import abstract
from ..core.properties import (
Alpha,
AnyRef,
Auto,
Bool,
Color,
Date,
Datetime,
Dict,
Either,
Enum,
Float,
Image,
Instance,
InstanceDefault,
Int,
List,
Null,
Nullable,
Override,
Percent,
Regex,
Required,
Seq,
String,
Tuple,
)
from ..core.validation import error
from ..core.validation.errors import (
INCOMPATIBLE_BOX_EDIT_RENDERER,
INCOMPATIBLE_LINE_EDIT_INTERSECTION_RENDERER,
INCOMPATIBLE_LINE_EDIT_RENDERER,
INCOMPATIBLE_POINT_DRAW_RENDERER,
INCOMPATIBLE_POLY_DRAW_RENDERER,
INCOMPATIBLE_POLY_EDIT_RENDERER,
INCOMPATIBLE_POLY_EDIT_VERTEX_RENDERER,
NO_RANGE_TOOL_RANGES,
)
from ..model import Model
from ..util.strings import nice_join
from .annotations import BoxAnnotation, PolyAnnotation, Span
from .callbacks import Callback
from .dom import Template
from .glyphs import (
Line,
LineGlyph,
MultiLine,
Patches,
Rect,
XYGlyph,
)
from .ranges import Range1d
from .renderers import DataRenderer, GlyphRenderer
from .ui import UIElement
#-----------------------------------------------------------------------------
# Globals and constants
#-----------------------------------------------------------------------------
__all__ = (
'ActionTool',
'BoxEditTool',
'BoxSelectTool',
'BoxZoomTool',
'CopyTool',
'CrosshairTool',
'CustomAction',
'CustomJSHover',
'Drag',
'EditTool',
'FreehandDrawTool',
'FullscreenTool',
'HelpTool',
'HoverTool',
'InspectTool',
'GestureTool',
'LassoSelectTool',
'LineEditTool',
'PanTool',
'PointDrawTool',
'PolyDrawTool',
'PolyEditTool',
'PolySelectTool',
'RangeTool',
'RedoTool',
'ResetTool',
'SaveTool',
'Scroll',
'ExamineTool',
'Tap',
'TapTool',
'Tool',
'ToolProxy',
'Toolbar',
'UndoTool',
'WheelPanTool',
'WheelZoomTool',
'ZoomInTool',
'ZoomOutTool',
)
#-----------------------------------------------------------------------------
# General API
#-----------------------------------------------------------------------------
[docs]@abstract
class Tool(Model):
''' A base class for all interactive tool types.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
icon = Nullable(Either(Enum(ToolIcon), Regex(r"^\."), Image), help="""
An icon to display in the toolbar.
The icon can provided as well known tool icon name, a CSS class selector,
a data URI with an ``image/*`` MIME, a path to an image, a PIL ``Image``
object, or an RGB(A) NumPy array. If ``None``, then the intrinsic icon
will be used (may depend on tool's configuration).
""")
description = Nullable(String, help="""
A string describing the purpose of this tool. If not defined, an auto-generated
description will be used. This description will be typically presented in the
user interface as a tooltip.
""")
_known_aliases: tp.ClassVar[dict[str, tp.Callable[[], Tool]]] = {}
[docs] @classmethod
def from_string(cls, name: str) -> Tool:
""" Takes a string and returns a corresponding `Tool` instance. """
constructor = cls._known_aliases.get(name)
if constructor is not None:
return constructor()
else:
known_names = cls._known_aliases.keys()
matches, text = difflib.get_close_matches(name.lower(), known_names), "similar"
if not matches:
matches, text = known_names, "possible"
raise ValueError(f"unexpected tool name '{name}', {text} tools are {nice_join(matches)}")
@classmethod
def register_alias(cls, name: str, constructor: tp.Callable[[], Tool]) -> None:
cls._known_aliases[name] = constructor
[docs]class ToolProxy(Model):
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
tools = List(Instance(Tool))
active = Bool(default=False)
disabled = Bool(default=False)
[docs]@abstract
class ActionTool(Tool):
''' A base class for tools that are buttons in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
@abstract
class PlotActionTool(ActionTool):
''' A base class action tools acting on plots.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]@abstract
class GestureTool(Tool):
''' A base class for tools that respond to drag events.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]@abstract
class Drag(GestureTool):
''' A base class for tools that respond to drag events.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]@abstract
class Scroll(GestureTool):
''' A base class for tools that respond to scroll events.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]@abstract
class Tap(GestureTool):
''' A base class for tools that respond to tap/click events.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
@abstract
class SelectTool(GestureTool):
''' A base class for tools that perform "selections", e.g. ``BoxSelectTool``.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
renderers = Either(Auto, List(Instance(DataRenderer)), default="auto", help="""
An explicit list of renderers to hit test against. If unset, defaults to
all renderers on a plot.
""")
mode = Enum(SelectionMode, default="replace", help="""
Defines what should happen when a new selection is made. The default
is to replace the existing selection. Other options are to append to
the selection, intersect with it or subtract from it.
""")
[docs]@abstract
class InspectTool(GestureTool):
''' A base class for tools that perform "inspections", e.g. ``HoverTool``.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
toggleable = Bool(True, help="""
Whether an on/off toggle button should appear in the toolbar for this
inspection tool. If ``False``, the viewers of a plot will not be able to
toggle the inspector on or off using the toolbar.
""")
[docs]class Toolbar(UIElement):
''' Collect tools to display for a single plot.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
logo = Nullable(Enum("normal", "grey"), default="normal", help="""
What version of the Bokeh logo to display on the toolbar. If
set to None, no logo will be displayed.
""")
autohide = Bool(default=False, help="""
Whether the toolbar will be hidden by default. Default: False.
If True, hides toolbar when cursor is not in canvas.
""")
tools = List(Either(Instance(Tool), Instance(ToolProxy)), help="""
A list of tools to add to the plot.
""")
active_drag: Literal["auto"] | Drag | None = Either(Null, Auto, Instance(Drag), default="auto", help="""
Specify a drag tool to be active when the plot is displayed.
""")
active_inspect: Literal["auto"] | InspectTool | tp.Sequence[InspectTool] | None = \
Either(Null, Auto, Instance(InspectTool), Seq(Instance(InspectTool)), default="auto", help="""
Specify an inspection tool or sequence of inspection tools to be active when
the plot is displayed.
""")
active_scroll: Literal["auto"] | Scroll | None = Either(Null, Auto, Instance(Scroll), default="auto", help="""
Specify a scroll/pinch tool to be active when the plot is displayed.
""")
active_tap: Literal["auto"] | Tap | None = Either(Null, Auto, Instance(Tap), default="auto", help="""
Specify a tap/click tool to be active when the plot is displayed.
""")
active_multi: Literal["auto"] | GestureTool | None = Either(Null, Auto, Instance(GestureTool), default="auto", help="""
Specify an active multi-gesture tool, for instance an edit tool or a range
tool.
Note that activating a multi-gesture tool will deactivate any other gesture
tools as appropriate. For example, if a pan tool is set as the active drag,
and this property is set to a ``BoxEditTool`` instance, the pan tool will
be deactivated (i.e. the multi-gesture tool will take precedence).
""")
[docs]class PanTool(Drag):
''' *toolbar icon*: |pan_icon|
The pan tool allows the user to pan a Plot by left-dragging a mouse, or on
touch devices by dragging a finger or stylus, across the plot region.
The pan tool also activates the border regions of a Plot for "single axis"
panning. For instance, dragging in the vertical border or axis will effect
a pan in the vertical direction only, with horizontal dimension kept fixed.
.. |pan_icon| image:: /_images/icons/Pan.png
:height: 24px
:alt: Icon of four arrows meeting in a plus shape representing the pan tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions the pan tool is constrained to act in. By default
the pan tool will pan in any dimension, but can be configured to only
pan horizontally across the width of the plot, or vertically across the
height of the plot.
""")
DEFAULT_RANGE_OVERLAY = InstanceDefault(BoxAnnotation,
syncable=False,
level="overlay",
fill_color="lightgrey",
fill_alpha=0.5,
line_color="black",
line_alpha=1.0,
line_width=0.5,
line_dash=[2,2],
)
[docs]class RangeTool(Drag):
''' *toolbar icon*: |range_icon|
The range tool allows the user to update range objects for either or both
of the x- or y-dimensions by dragging a corresponding shaded annotation to
move it or change its boundaries.
A common use case is to add this tool to a plot with a large fixed range,
but to configure the tool range from a different plot. When the user
manipulates the overlay, the range of the second plot will be updated
automatically.
.. |range_icon| image:: /_images/icons/Range.png
:height: 24px
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
x_range = Nullable(Instance(Range1d), help="""
A range synchronized to the x-dimension of the overlay. If None, the overlay
will span the entire x-dimension.
""")
x_interaction = Bool(default=True, help="""
Whether to respond to horizontal pan motions when an ``x_range`` is present.
By default, when an ``x_range`` is specified, it is possible to adjust the
horizontal position of the range box by panning horizontally inside the
box, or along the top or bottom edge of the box. To disable this, and fix
the range box in place horizontally, set to False. (The box will still
update if the ``x_range`` is updated programmatically.)
""")
y_range = Nullable(Instance(Range1d), help="""
A range synchronized to the y-dimension of the overlay. If None, the overlay
will span the entire y-dimension.
""")
y_interaction = Bool(default=True, help="""
Whether to respond to vertical pan motions when a ``y_range`` is present.
By default, when a ``y_range`` is specified, it is possible to adjust the
vertical position of the range box by panning vertically inside the box, or
along the top or bottom edge of the box. To disable this, and fix the range
box in place vertically, set to False. (The box will still update if the
``y_range`` is updated programmatically.)
""")
overlay = Instance(BoxAnnotation, default=DEFAULT_RANGE_OVERLAY, help="""
A shaded annotation drawn to indicate the configured ranges.
""")
@error(NO_RANGE_TOOL_RANGES)
def _check_no_range_tool_ranges(self):
if self.x_range is None and self.y_range is None:
return "At least one of RangeTool.x_range or RangeTool.y_range must be configured"
[docs]class WheelPanTool(Scroll):
''' *toolbar icon*: |wheel_pan_icon|
The wheel pan tool allows the user to pan the plot along the configured
dimension using the scroll wheel.
.. |wheel_pan_icon| image:: /_images/icons/WheelPan.png
:height: 24px
:alt: Icon of a mouse shape next to crossed arrows representing the wheel-pan tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
dimension = Enum(Dimension, default="width", help="""
Which dimension the wheel pan tool is constrained to act in. By default the
wheel pan tool will pan the plot along the x-axis.
""")
[docs]class WheelZoomTool(Scroll):
''' *toolbar icon*: |wheel_zoom_icon|
The wheel zoom tool will zoom the plot in and out, centered on the
current mouse location.
The wheel zoom tool also activates the border regions of a Plot for
"single axis" zooming. For instance, zooming in the vertical border or
axis will effect a zoom in the vertical direction only, with the
horizontal dimension kept fixed.
.. |wheel_zoom_icon| image:: /_images/icons/WheelZoom.png
:height: 24px
:alt: Icon of a mouse shape next to an hourglass representing the wheel-zoom tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions the wheel zoom tool is constrained to act in. By default
the wheel zoom tool will zoom in any dimension, but can be configured to
only zoom horizontally across the width of the plot, or vertically across
the height of the plot.
""")
maintain_focus = Bool(default=True, help="""
If True, then hitting a range bound in any one dimension will prevent all
further zooming all dimensions. If False, zooming can continue
independently in any dimension that has not yet reached its bounds, even if
that causes overall focus or aspect ratio to change.
""")
zoom_on_axis = Bool(default=True, help="""
Whether scrolling on an axis (outside the central plot area) should zoom
that dimension.
""")
speed = Float(default=1/600, help="""
Speed at which the wheel zooms. Default is 1/600. Optimal range is between
0.001 and 0.09. High values will be clipped. Speed may very between browsers.
""")
[docs]class CustomAction(ActionTool):
''' Execute a custom action, e.g. ``CustomJS`` callback when a toolbar
icon is activated.
Example:
.. code-block:: python
tool = CustomAction(icon="icon.png",
callback=CustomJS(code='alert("foo")'))
plot.add_tools(tool)
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
description = Override(default="Perform a Custom Action")
callback = Nullable(Instance(Callback), help="""
A Bokeh callback to execute when the custom action icon is activated.
""")
[docs]class SaveTool(ActionTool):
''' *toolbar icon*: |save_icon|
The save tool is an action. When activated, the tool opens a download dialog
which allows to save an image reproduction of the plot in PNG format. If
automatic download is not support by a web browser, the tool falls back to
opening the generated image in a new tab or window. User then can manually
save it by right clicking on the image and choosing "Save As" (or similar)
menu item.
.. |save_icon| image:: /_images/icons/Save.png
:height: 24px
:alt: Icon of a floppy disk representing the save tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
filename = Nullable(String, help="""
Optional string specifying the filename of the saved image (extension not
needed). If a filename is not provided or set to None, the user is prompted
for a filename at save time.
""")
[docs]class CopyTool(ActionTool):
''' *toolbar icon*: |copy_icon|
The copy tool is an action tool, that allows copying the rendererd contents of
a plot or a collection of plots to system's clipboard. This tools is browser
dependent and may not function in certain browsers, or require additional
permissions to be granted to the web page.
.. |copy_icon| image:: /_images/icons/Copy.png
:height: 24px
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]class ResetTool(PlotActionTool):
''' *toolbar icon*: |reset_icon|
The reset tool is an action. When activated in the toolbar, the tool resets
the data bounds of the plot to their values when the plot was initially
created.
.. |reset_icon| image:: /_images/icons/Reset.png
:height: 24px
:alt: Icon of two arrows on a circular arc forming a circle representing the reset tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]class TapTool(Tap, SelectTool):
''' *toolbar icon*: |tap_icon|
The tap selection tool allows the user to select at single points by
left-clicking a mouse, or tapping with a finger.
See :ref:`ug_styling_plots_selected_unselected_glyphs` for information
on styling selected and unselected glyphs.
.. |tap_icon| image:: /_images/icons/Tap.png
:height: 24px
:alt: Icon of two concentric circles with a + in the lower right representing the tap tool in the toolbar.
.. note::
Selections can be comprised of multiple regions, even those
made by different selection tools. Hold down the <<shift>> key
while making a selection to append the new selection to any
previous selection that might exist.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
behavior = Enum("select", "inspect", default="select", help="""
This tool can be configured to either make selections or inspections
on associated data sources. The difference is that selection changes
propagate across bokeh and other components (e.g. selection glyph)
will be notified. Inspections don't act like this, so it's useful to
configure `callback` when setting `behavior='inspect'`.
""")
gesture = Enum("tap", "doubletap", default="tap", help="""
Specifies which kind of gesture will be used to trigger the tool,
either a single or double tap.
""")
callback = Nullable(Instance(Callback), help="""
A callback to execute *whenever a glyph is "hit"* by a mouse click
or tap.
This is often useful with the :class:`~bokeh.models.callbacks.OpenURL`
model to open URLs based on a user clicking or tapping a specific glyph.
However, it may also be a :class:`~bokeh.models.callbacks.CustomJS`
which can execute arbitrary JavaScript code in response to clicking or
tapping glyphs. The callback will be executed for each individual glyph
that is it hit by a click or tap, and will receive the ``TapTool`` model
as ``cb_obj``. The optional ``cb_data`` will have the data source as
its ``.source`` attribute and the selection geometry as its
``.geometries`` attribute.
The ``.geometries`` attribute has 5 members.
``.type`` is the geometry type, which always a ``.point`` for a tap event.
``.sx`` and ``.sy`` are the screen X and Y coordinates where the tap occurred.
``.x`` and ``.y`` are the converted data coordinates for the item that has
been selected. The ``.x`` and ``.y`` values are based on the axis assigned
to that glyph.
.. note::
This callback does *not* execute on every tap, only when a glyph is
"hit". If you would like to execute a callback on every mouse tap,
please see :ref:`ug_interaction_js_callbacks_customjs_js_on_event`.
""")
[docs]class CrosshairTool(InspectTool):
''' *toolbar icon*: |crosshair_icon|
The crosshair tool is a passive inspector tool. It is generally on at all
times, but can be configured in the inspector's menu associated with the
*toolbar icon* shown above.
The crosshair tool draws a crosshair annotation over the plot, centered on
the current mouse position. The crosshair tool may be configured to draw
across only one dimension by setting the ``dimension`` property to only
``width`` or ``height``.
.. |crosshair_icon| image:: /_images/icons/Crosshair.png
:height: 24px
:alt: Icon of circle with aiming reticle marks representing the crosshair tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
overlay = Either(
Auto,
Instance(Span),
Tuple(Instance(Span), Instance(Span)), default="auto", help="""
An annotation drawn to indicate the crosshair.
If ``"auto"``, this will create spans depending on the ``dimensions``
property, which based on its value, will result in either one span
(horizontal or vertical) or two spans (horizontal and vertical).
Alternatively the user can provide one ``Span`` instance, where the
dimension is indicated by the ``dimension`` property of the ``Span``.
Also two ``Span`` instances can be provided. Providing explicit
``Span`` instances allows for constructing linked crosshair, when
those instances are shared between crosshair tools of different plots.
.. note::
This property is experimental and may change at any point. In
particular in future this will allow using other annotations
than ``Span`` and annotation groups.
""")
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions the crosshair tool is to track. By default, both vertical
and horizontal lines will be drawn. If only "width" is supplied, only a
horizontal line will be drawn. If only "height" is supplied, only a
vertical line will be drawn.
""")
line_color = Color(default="black", help="""
A color to use to stroke paths with.
""")
line_alpha = Alpha(help="""
An alpha value to use to stroke paths with.
""")
line_width = Float(default=1, help="""
Stroke width in units of pixels.
""")
DEFAULT_BOX_OVERLAY = InstanceDefault(BoxAnnotation,
syncable=False,
level="overlay",
visible=False,
top_units="canvas",
left_units="canvas",
bottom_units="canvas",
right_units="canvas",
fill_color="lightgrey",
fill_alpha=0.5,
line_color="black",
line_alpha=1.0,
line_width=2,
line_dash=[4, 4],
)
[docs]class BoxZoomTool(Drag):
''' *toolbar icon*: |box_zoom_icon|
The box zoom tool allows users to define a rectangular egion of a Plot to
zoom to by dragging he mouse or a finger over the plot region. The end of
the drag event indicates the selection region is ready.
.. |box_zoom_icon| image:: /_images/icons/BoxZoom.png
:height: 24px
:alt: Icon of a dashed box with a magnifying glass in the upper right representing the box-zoom tool in the toolbar.
.. note::
``BoxZoomTool`` is incompatible with ``GMapPlot`` due to the manner in
which Google Maps exert explicit control over aspect ratios. Adding
this tool to a ``GMapPlot`` will have no effect.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
dimensions = Either(Enum(Dimensions), Auto, default="both", help="""
Which dimensions the zoom box is to be free in. By default, users may
freely draw zoom boxes with any dimensions. If only "width" is supplied,
the box will be constrained to span the entire vertical space of the plot,
only the horizontal dimension can be controlled. If only "height" is
supplied, the box will be constrained to span the entire horizontal space
of the plot, and the vertical dimension can be controlled.
""")
overlay = Instance(BoxAnnotation, default=DEFAULT_BOX_OVERLAY, help="""
A shaded annotation drawn to indicate the selection region.
""")
match_aspect = Bool(default=False, help="""
Whether the box zoom region should be restricted to have the same
aspect ratio as the plot region.
.. note::
If the tool is restricted to one dimension, this value has
no effect.
""")
origin = Enum("corner", "center", default="corner", help="""
Indicates whether the rectangular zoom area should originate from a corner
(top-left or bottom-right depending on direction) or the center of the box.
""")
[docs]class ZoomInTool(PlotActionTool):
''' *toolbar icon*: |zoom_in_icon|
The zoom-in tool allows users to click a button to zoom in
by a fixed amount.
.. |zoom_in_icon| image:: /_images/icons/ZoomIn.png
:height: 24px
:alt: Icon of a plus sign next to a magnifying glass representing the zoom-in tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
# TODO ZoomInTool dimensions should probably be constrained to be the same as ZoomOutTool
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions the zoom-in tool is constrained to act in. By default the
zoom-in zoom tool will zoom in any dimension, but can be configured to only
zoom horizontally across the width of the plot, or vertically across the
height of the plot.
""")
factor = Percent(default=0.1, help="""
Percentage to zoom for each click of the zoom-in tool.
""")
[docs]class ZoomOutTool(PlotActionTool):
''' *toolbar icon*: |zoom_out_icon|
The zoom-out tool allows users to click a button to zoom out
by a fixed amount.
.. |zoom_out_icon| image:: /_images/icons/ZoomOut.png
:height: 24px
:alt: Icon of a minus sign next to a magnifying glass representing the zoom-out tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions the zoom-out tool is constrained to act in. By default the
zoom-out tool will zoom in any dimension, but can be configured to only
zoom horizontally across the width of the plot, or vertically across the
height of the plot.
""")
factor = Percent(default=0.1, help="""
Percentage to zoom for each click of the zoom-in tool.
""")
maintain_focus = Bool(default=True, help="""
If True, then hitting a range bound in any one dimension will prevent all
further zooming all dimensions. If False, zooming can continue
independently in any dimension that has not yet reached its bounds, even if
that causes overall focus or aspect ratio to change.
""")
[docs]class BoxSelectTool(Drag, SelectTool):
''' *toolbar icon*: |box_select_icon|
The box selection tool allows users to make selections on a Plot by showing
a rectangular region by dragging the mouse or a finger over the plot area.
The end of the drag event indicates the selection region is ready.
See :ref:`ug_styling_plots_selected_unselected_glyphs` for information
on styling selected and unselected glyphs.
.. |box_select_icon| image:: /_images/icons/BoxSelect.png
:height: 24px
:alt: Icon of a dashed box with a + in the lower right representing the box-selection tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
select_every_mousemove = Bool(False, help="""
Whether a selection computation should happen on every mouse event, or only
once, when the selection region is completed. Default: False
""")
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions the box selection is to be free in. By default, users may
freely draw selections boxes with any dimensions. If only "width" is set,
the box will be constrained to span the entire vertical space of the plot,
only the horizontal dimension can be controlled. If only "height" is set,
the box will be constrained to span the entire horizontal space of the
plot, and the vertical dimension can be controlled.
""")
overlay = Instance(BoxAnnotation, default=DEFAULT_BOX_OVERLAY, help="""
A shaded annotation drawn to indicate the selection region.
""")
origin = Enum("corner", "center", default="corner", help="""
Indicates whether the rectangular selection area should originate from a corner
(top-left or bottom-right depending on direction) or the center of the box.
""")
DEFAULT_POLY_OVERLAY = InstanceDefault(PolyAnnotation,
syncable=False,
level="overlay",
visible=False,
xs_units="canvas",
ys_units="canvas",
fill_color="lightgrey",
fill_alpha=0.5,
line_color="black",
line_alpha=1.0,
line_width=2,
line_dash=[4, 4]
)
[docs]class LassoSelectTool(Drag, SelectTool):
''' *toolbar icon*: |lasso_select_icon|
The lasso selection tool allows users to make selections on a Plot by
indicating a free-drawn "lasso" region by dragging the mouse or a finger
over the plot region. The end of the drag event indicates the selection
region is ready.
See :ref:`ug_styling_plots_selected_unselected_glyphs` for information
on styling selected and unselected glyphs.
.. note::
Selections can be comprised of multiple regions, even those made by
different selection tools. Hold down the <<shift>> key while making a
selection to append the new selection to any previous selection that
might exist.
.. |lasso_select_icon| image:: /_images/icons/LassoSelect.png
:height: 24px
:alt: Icon of a looped lasso shape representing the lasso-selection tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
select_every_mousemove = Bool(True, help="""
Whether a selection computation should happen on every mouse event, or only
once, when the selection region is completed.
""")
overlay = Instance(PolyAnnotation, default=DEFAULT_POLY_OVERLAY, help="""
A shaded annotation drawn to indicate the selection region.
""")
[docs]class PolySelectTool(Tap, SelectTool):
''' *toolbar icon*: |poly_select_icon|
The polygon selection tool allows users to make selections on a
Plot by indicating a polygonal region with mouse clicks. single
clicks (or taps) add successive points to the definition of the
polygon, and a double click (or tap) indicates the selection
region is ready.
See :ref:`ug_styling_plots_selected_unselected_glyphs` for information
on styling selected and unselected glyphs.
.. note::
Selections can be comprised of multiple regions, even those
made by different selection tools. Hold down the <<shift>> key
while making a selection to append the new selection to any
previous selection that might exist.
.. |poly_select_icon| image:: /_images/icons/PolygonSelect.png
:height: 24px
:alt: Icon of a dashed trapezoid with an arrow pointing at the lower right representing the polygon-selection tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
overlay = Instance(PolyAnnotation, default=DEFAULT_POLY_OVERLAY, help="""
A shaded annotation drawn to indicate the selection region.
""")
[docs]class CustomJSHover(Model):
''' Define a custom formatter to apply to a hover tool field.
This model can be configured with JavaScript code to format hover tooltips.
The JavaScript code has access to the current value to format, some special
variables, and any format configured on the tooltip. The variable ``value``
will contain the untransformed value. The variable ``special_vars`` will
provide a dict with the following contents:
* ``x`` data-space x-coordinate of the mouse
* ``y`` data-space y-coordinate of the mouse
* ``sx`` screen-space x-coordinate of the mouse
* ``sy`` screen-space y-coordinate of the mouse
* ``data_x`` data-space x-coordinate of the hovered glyph
* ``data_y`` data-space y-coordinate of the hovered glyph
* ``indices`` column indices of all currently hovered glyphs
* ``name`` value of the ``name`` property of the hovered glyph renderer
If the hover is over a "multi" glyph such as ``Patches`` or ``MultiLine``
then a ``segment_index`` key will also be present.
Finally, the value of the format passed in the tooltip specification is
available as the ``format`` variable.
Example:
As an example, the following code adds a custom formatter to format
WebMercator northing coordinates (in meters) as a latitude:
.. code-block:: python
lat_custom = CustomJSHover(code="""
const projections = Bokeh.require("core/util/projections");
const x = special_vars.x
const y = special_vars.y
const coords = projections.wgs84_mercator.invert(x, y)
return "" + coords[1]
""")
p.add_tools(HoverTool(
tooltips=[( 'lat','@y{custom}' )],
formatters={'@y':lat_custom}
))
.. warning::
The explicit purpose of this Bokeh Model is to embed *raw JavaScript
code* for a browser to execute. If any part of the code is derived
from untrusted user inputs, then you must take appropriate care to
sanitize the user input prior to passing to Bokeh.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
args = Dict(String, AnyRef, help="""
A mapping of names to Bokeh plot objects. These objects are made available
to the callback code snippet as the values of named parameters to the
callback.
""")
code = String(default="", help="""
A snippet of JavaScript code to transform a single value. The variable
``value`` will contain the untransformed value and can be expected to be
present in the function namespace at render time. Additionally, the
variable ``special_vars`` will be available, and will provide a dict
with the following contents:
* ``x`` data-space x-coordinate of the mouse
* ``y`` data-space y-coordinate of the mouse
* ``sx`` screen-space x-coordinate of the mouse
* ``sy`` screen-space y-coordinate of the mouse
* ``data_x`` data-space x-coordinate of the hovered glyph
* ``data_y`` data-space y-coordinate of the hovered glyph
* ``indices`` column indices of all currently hovered glyphs
If the hover is over a "multi" glyph such as ``Patches`` or ``MultiLine``
then a ``segment_index`` key will also be present.
Finally, the value of the format passed in the tooltip specification is
available as the ``format`` variable.
The snippet will be made into the body of a function and therefore requires
a return statement.
Example:
.. code-block:: javascript
code = '''
return value + " total"
'''
""")
[docs]class HoverTool(InspectTool):
''' *toolbar icon*: |hover_icon|
The hover tool is a passive inspector tool. It is generally on at all
times, but can be configured in the inspector's menu associated with the
*toolbar icon* shown above.
By default, the hover tool displays informational tooltips whenever the
cursor is directly over a glyph. The data to show comes from the glyph's
data source, and what to display is configurable with the ``tooltips``
property that maps display names to columns in the data source, or to
special known variables.
Here is an example of how to configure and use the hover tool::
# Add tooltip (name, field) pairs to the tool. See below for a
# description of possible field values.
hover.tooltips = [
("index", "$index"),
("(x,y)", "($x, $y)"),
("radius", "@radius"),
("fill color", "$color[hex, swatch]:fill_color"),
("fill color", "$color[hex]:fill_color"),
("fill color", "$color:fill_color"),
("fill color", "$swatch:fill_color"),
("foo", "@foo"),
("bar", "@bar"),
("baz", "@baz{safe}"),
("total", "@total{$0,0.00}"
]
You can also supply a ``Callback`` to the ``HoverTool``, to build custom
interactions on hover. In this case you may want to turn the tooltips
off by setting ``tooltips=None``.
.. warning::
When supplying a callback or custom template, the explicit intent
of this Bokeh Model is to embed *raw HTML and JavaScript code* for
a browser to execute. If any part of the code is derived from untrusted
user inputs, then you must take appropriate care to sanitize the user
input prior to passing to Bokeh.
Hover tool does not currently work with the following glyphs:
.. hlist::
:columns: 3
* annulus
* arc
* bezier
* image_url
* oval
* patch
* quadratic
* ray
* step
* text
.. |hover_icon| image:: /_images/icons/Hover.png
:height: 24px
:alt: Icon of a popup tooltip with abstract lines of text representing the hover tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
renderers = Either(Auto, List(Instance(DataRenderer)), default="auto", help="""
An explicit list of renderers to hit test against. If unset, defaults to
all renderers on a plot.
""")
callback = Nullable(Instance(Callback), help="""
A callback to run in the browser whenever the input's value changes. The
``cb_data`` parameter that is available to the Callback code will contain two
``HoverTool`` specific fields:
:index: object containing the indices of the hovered points in the data source
:geometry: object containing the coordinates of the hover cursor
""")
tooltips = Either(Null, Instance(Template), String, List(Tuple(String, String)),
default=[
("index","$index"),
("data (x, y)","($x, $y)"),
("screen (x, y)","($sx, $sy)"),
], help="""
The (name, field) pairs describing what the hover tool should
display when there is a hit.
Field names starting with "@" are interpreted as columns on the
data source. For instance, "@temp" would look up values to display
from the "temp" column of the data source.
Field names starting with "$" are special, known fields:
:$index: index of hovered point in the data source
:$name: value of the ``name`` property of the hovered glyph renderer
:$x: x-coordinate under the cursor in data space
:$y: y-coordinate under the cursor in data space
:$sx: x-coordinate under the cursor in screen (canvas) space
:$sy: y-coordinate under the cursor in screen (canvas) space
:$color: color data from data source, with the syntax:
``$color[options]:field_name``. The available options
are: ``hex`` (to display the color as a hex value), ``swatch``
(color data from data source displayed as a small color box)
:$swatch: color data from data source displayed as a small color box
Field names that begin with ``@`` are associated with columns in a
``ColumnDataSource``. For instance the field name ``"@price"`` will
display values from the ``"price"`` column whenever a hover is triggered.
If the hover is for the 17th glyph, then the hover tooltip will
correspondingly display the 17th price value.
Note that if a column name contains spaces, the it must be supplied by
surrounding it in curly braces, e.g. ``@{adjusted close}`` will display
values from a column named ``"adjusted close"``.
Sometimes (especially with stacked charts) it is desirable to allow the
name of the column be specified indirectly. The field name ``@$name`` is
distinguished in that it will look up the ``name`` field on the hovered
glyph renderer, and use that value as the column name. For instance, if
a user hovers with the name ``"US East"``, then ``@$name`` is equivalent to
``@{US East}``.
By default, values for fields (e.g. ``@foo``) are displayed in a basic
numeric format. However it is possible to control the formatting of values
more precisely. Fields can be modified by appending a format specified to
the end in curly braces. Some examples are below.
.. code-block:: python
"@foo{0,0.000}" # formats 10000.1234 as: 10,000.123
"@foo{(.00)}" # formats -10000.1234 as: (10000.123)
"@foo{($ 0.00 a)}" # formats 1230974 as: $ 1.23 m
Specifying a format ``{safe}`` after a field name will override automatic
escaping of the tooltip data source. Any HTML tags in the data tags will
be rendered as HTML in the resulting HoverTool output. See
:ref:`custom_hover_tooltip` for a more detailed example.
``None`` is also a valid value for tooltips. This turns off the
rendering of tooltips. This is mostly useful when supplying other
actions on hover via the callback property.
.. note::
The tooltips attribute can also be configured with a mapping type,
e.g. ``dict`` or ``OrderedDict``.
""").accepts(Dict(String, String), lambda d: list(d.items()))
formatters = Dict(String, Either(Enum(TooltipFieldFormatter), Instance(CustomJSHover)), default=lambda: dict(), help="""
Specify the formatting scheme for data source columns, e.g.
.. code-block:: python
tool.formatters = {"@date": "datetime"}
will cause format specifications for the "date" column to be interpreted
according to the "datetime" formatting scheme. The following schemes are
available:
:``"numeral"``:
Provides a wide variety of formats for numbers, currency, bytes, times,
and percentages. The full set of formats can be found in the
|NumeralTickFormatter| reference documentation.
:``"datetime"``:
Provides formats for date and time values. The full set of formats is
listed in the |DatetimeTickFormatter| reference documentation.
:``"printf"``:
Provides formats similar to C-style "printf" type specifiers. See the
|PrintfTickFormatter| reference documentation for complete details.
If no formatter is specified for a column name, the default ``"numeral"``
formatter is assumed.
.. |NumeralTickFormatter| replace:: :class:`~bokeh.models.formatters.NumeralTickFormatter`
.. |DatetimeTickFormatter| replace:: :class:`~bokeh.models.formatters.DatetimeTickFormatter`
.. |PrintfTickFormatter| replace:: :class:`~bokeh.models.formatters.PrintfTickFormatter`
""")
mode = Enum("mouse", "hline", "vline", help="""
Whether to consider hover pointer as a point (x/y values), or a
span on h or v directions.
""")
muted_policy = Enum("show", "ignore",
default="show", help="""
Whether to avoid showing tooltips on muted glyphs.
""")
point_policy = Enum("snap_to_data", "follow_mouse", "none", help="""
Whether the tooltip position should snap to the "center" (or other anchor)
position of the associated glyph, or always follow the current mouse cursor
position.
""")
line_policy = Enum("prev", "next", "nearest", "interp", "none",
default="nearest", help="""
When showing tooltips for lines, designates whether the tooltip position
should be the "previous" or "next" points on the line, the "nearest" point
to the current mouse position, or "interpolate" along the line to the
current mouse position.
""")
anchor = Enum(Anchor, default="center", help="""
If point policy is set to `"snap_to_data"`, `anchor` defines the attachment
point of a tooltip. The default is to attach to the center of a glyph.
""")
attachment = Enum(TooltipAttachment, help="""
Whether the tooltip should be displayed to the left or right of the cursor
position or above or below it, or if it should be automatically placed
in the horizontal or vertical dimension.
""")
show_arrow = Bool(default=True, help="""
Whether tooltip's arrow should be shown.
""")
DEFAULT_HELP_TIP = "Click the question mark to learn more about Bokeh plot tools."
DEFAULT_HELP_URL = "https://docs.bokeh.org/en/latest/docs/user_guide/tools.html"
[docs]class HelpTool(ActionTool):
''' A button tool to provide a "help" link to users.
The hover text can be customized through the ``help_tooltip`` attribute
and the redirect site overridden as well.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
description = Override(default=DEFAULT_HELP_TIP)
redirect = String(default=DEFAULT_HELP_URL, help="""
Site to be redirected through upon click.
""")
[docs]class ExamineTool(ActionTool):
''' A tool that allows to inspect and configure a model. '''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]class FullscreenTool(ActionTool):
''' A tool that allows to enlarge a UI element to fullscreen. '''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]class UndoTool(PlotActionTool):
''' *toolbar icon*: |undo_icon|
Undo tool allows to restore previous state of the plot.
.. |undo_icon| image:: /_images/icons/Undo.png
:height: 24px
:alt: Icon of an arrow on a circular arc pointing to the left representing the undo tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]class RedoTool(PlotActionTool):
''' *toolbar icon*: |redo_icon|
Redo tool reverses the last action performed by undo tool.
.. |redo_icon| image:: /_images/icons/Redo.png
:height: 24px
:alt: Icon of an arrow on a circular arc pointing to the right representing the redo tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
[docs]@abstract
class EditTool(GestureTool):
''' A base class for all interactive draw tool types.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
empty_value = Required(Either(Bool, Int, Float, Date, Datetime, Color, String), help="""
Defines the value to insert on non-coordinate columns when a new
glyph is inserted into the ``ColumnDataSource`` columns, e.g. when a
circle glyph defines 'x', 'y' and 'color' columns, adding a new
point will add the x and y-coordinates to 'x' and 'y' columns and
the color column will be filled with the defined empty value.
""")
renderers = List(Instance(GlyphRenderer), help="""
An explicit list of renderers corresponding to glyphs that may be edited.
.. note::
The kind of renderer will typically depend on the specific type of the
edit tool subclass. For instance, ``PointDrawTool`` expects renderers
for ``Scatter`` glyphs, while ``BoxEditTool`` expects renderers for
``Rect`` glyphs, etc.
""")
@abstract
class PolyTool(EditTool):
''' A base class for polygon draw/edit tools. '''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
vertex_renderer = Nullable(Instance(GlyphRenderer), help="""
The renderer used to render the vertices of a selected line or polygon.
""")
@error(INCOMPATIBLE_POLY_EDIT_VERTEX_RENDERER)
def _check_compatible_vertex_renderer(self):
if self.vertex_renderer is None:
return
glyph = self.vertex_renderer.glyph
if not isinstance(glyph, XYGlyph):
return "glyph type %s found." % type(glyph).__name__
[docs]class BoxEditTool(EditTool, Drag, Tap):
''' *toolbar icon*: |box_edit_icon|
Allows drawing, dragging and deleting ``Rect`` glyphs on one or more
renderers by editing the underlying ``ColumnDataSource`` data. Like other
drawing tools, the renderers that are to be edited must be supplied
explicitly as a list. When drawing a new box the data will always be added
to the ``ColumnDataSource`` on the first supplied renderer.
The tool will modify the columns on the data source corresponding to the
``x``, ``y``, ``width`` and ``height`` values of the glyph. Any additional
columns in the data source will be padded with ``empty_value``, when adding
a new box.
The supported actions include:
* Add box: Hold shift then click and drag anywhere on the plot or double
tap once to start drawing, move the mouse and double tap again to finish
drawing.
* Move box: Click and drag an existing box, the box will be dropped once
you let go of the mouse button.
* Delete box: Tap a box to select it then press <<backspace>> key while the
mouse is within the plot area.
To **Move** or **Delete** multiple boxes at once:
* Move selection: Select box(es) with <<shift>>+tap (or another selection
tool) then drag anywhere on the plot. Selecting and then dragging on a
specific box will move both.
* Delete selection: Select box(es) with <<shift>>+tap (or another selection
tool) then press <<backspace>> while the mouse is within the plot area.
.. |box_edit_icon| image:: /_images/icons/BoxEdit.png
:height: 24px
:alt: Icon of a solid line box with a plus sign in the lower right representing the box-edit tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions the box drawing is to be free in. By default, users may
freely draw boxes with any dimensions. If only "width" is set, the box will
be constrained to span the entire vertical space of the plot, only the
horizontal dimension can be controlled. If only "height" is set, the box
will be constrained to span the entire horizontal space of the plot, and the
vertical dimension can be controlled.
""")
num_objects = Int(default=0, help="""
Defines a limit on the number of boxes that can be drawn. By default there
is no limit on the number of objects, but if enabled the oldest drawn box
will be dropped to make space for the new box being added.
""")
@error(INCOMPATIBLE_BOX_EDIT_RENDERER)
def _check_compatible_renderers(self):
incompatible_renderers = []
for renderer in self.renderers:
if not isinstance(renderer.glyph, Rect):
incompatible_renderers.append(renderer)
if incompatible_renderers:
glyph_types = ', '.join(type(renderer.glyph).__name__ for renderer in incompatible_renderers)
return "%s glyph type(s) found." % glyph_types
[docs]class PointDrawTool(EditTool, Drag, Tap):
''' *toolbar icon*: |point_draw_icon|
The PointDrawTool allows adding, dragging and deleting point-like glyphs
(i.e subclasses of``XYGlyph``) on one or more renderers by editing the
underlying ``ColumnDataSource`` data. Like other drawing tools, the
renderers that are to be edited must be supplied explicitly as a list. Any
newly added points will be inserted on the ``ColumnDataSource`` of the
first supplied renderer.
The tool will modify the columns on the data source corresponding to the
``x`` and ``y`` values of the glyph. Any additional columns in the data
source will be padded with the given ``empty_value`` when adding a new
point.
.. note::
The data source updates will trigger data change events continuously
throughout the edit operations on the BokehJS side. In Bokeh server
apps, the data source will only be synced once, when the edit operation
finishes.
The supported actions include:
* Add point: Tap anywhere on the plot
* Move point: Tap and drag an existing point, the point will be
dropped once you let go of the mouse button.
* Delete point: Tap a point to select it then press <<backspace>>
key while the mouse is within the plot area.
.. |point_draw_icon| image:: /_images/icons/PointDraw.png
:height: 24px
:alt: Icon of three points with an arrow pointing to one representing the point-edit tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
add = Bool(default=True, help="""
Enables adding of new points on tap events.
""")
drag = Bool(default=True, help="""
Enables dragging of existing points on pan events.
""")
num_objects = Int(default=0, help="""
Defines a limit on the number of points that can be drawn. By default there
is no limit on the number of objects, but if enabled the oldest drawn point
will be dropped to make space for the new point.
""")
@error(INCOMPATIBLE_POINT_DRAW_RENDERER)
def _check_compatible_renderers(self):
incompatible_renderers = []
for renderer in self.renderers:
if not isinstance(renderer.glyph, XYGlyph):
incompatible_renderers.append(renderer)
if incompatible_renderers:
glyph_types = ', '.join(type(renderer.glyph).__name__ for renderer in incompatible_renderers)
return "%s glyph type(s) found." % glyph_types
[docs]class PolyDrawTool(PolyTool, Drag, Tap):
''' *toolbar icon*: |poly_draw_icon|
The PolyDrawTool allows drawing, selecting and deleting ``Patches`` and
``MultiLine`` glyphs on one or more renderers by editing the underlying
``ColumnDataSource`` data. Like other drawing tools, the renderers that
are to be edited must be supplied explicitly.
The tool will modify the columns on the data source corresponding to the
``xs`` and ``ys`` values of the glyph. Any additional columns in the data
source will be padded with the declared ``empty_value``, when adding a new
point.
If a ``vertex_renderer`` with an point-like glyph is supplied then the
``PolyDrawTool`` will use it to display the vertices of the multi-lines or
patches on all supplied renderers. This also enables the ability to snap
to existing vertices while drawing.
The supported actions include:
* Add patch or multi-line: Double tap to add the first vertex, then use tap
to add each subsequent vertex, to finalize the draw action double tap to
insert the final vertex or press the <<esc> key.
* Move patch or ulti-line: Tap and drag an existing patch/multi-line, the
point will be dropped once you let go of the mouse button.
* Delete patch or multi-line: Tap a patch/multi-line to select it then
press <<backspace>> key while the mouse is within the plot area.
.. |poly_draw_icon| image:: /_images/icons/PolyDraw.png
:height: 24px
:alt: Icon of a solid line trapezoid with an arrow pointing at the lower right representing the polygon-draw tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
drag = Bool(default=True, help="""
Enables dragging of existing patches and multi-lines on pan events.
""")
num_objects = Int(default=0, help="""
Defines a limit on the number of patches or multi-lines that can be drawn.
By default there is no limit on the number of objects, but if enabled the
oldest drawn patch or multi-line will be dropped to make space for the new
patch or multi-line.
""")
@error(INCOMPATIBLE_POLY_DRAW_RENDERER)
def _check_compatible_renderers(self):
incompatible_renderers = []
for renderer in self.renderers:
if not isinstance(renderer.glyph, (MultiLine, Patches)):
incompatible_renderers.append(renderer)
if incompatible_renderers:
glyph_types = ', '.join(type(renderer.glyph).__name__ for renderer in incompatible_renderers)
return "%s glyph type(s) found." % glyph_types
[docs]class FreehandDrawTool(EditTool, Drag, Tap):
''' *toolbar icon*: |freehand_draw_icon|
Allows freehand drawing of ``Patches`` and ``MultiLine`` glyphs. The glyph
to draw may be defined via the ``renderers`` property.
The tool will modify the columns on the data source corresponding to the
``xs`` and ``ys`` values of the glyph. Any additional columns in the data
source will be padded with the declared ``empty_value``, when adding a new
point.
The supported actions include:
* Draw vertices: Click and drag to draw a line
* Delete patch/multi-line: Tap a patch/multi-line to select it then press
<<backspace>> key while the mouse is within the plot area.
.. |freehand_draw_icon| image:: /_images/icons/FreehandDraw.png
:height: 24px
:alt: Icon of a pen drawing a wavy line representing the freehand-draw tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
num_objects = Int(default=0, help="""
Defines a limit on the number of patches or multi-lines that can be drawn.
By default there is no limit on the number of objects, but if enabled the
oldest drawn patch or multi-line will be overwritten when the limit is
reached.
""")
@error(INCOMPATIBLE_POLY_DRAW_RENDERER)
def _check_compatible_renderers(self):
incompatible_renderers = []
for renderer in self.renderers:
if not isinstance(renderer.glyph, (MultiLine, Patches)):
incompatible_renderers.append(renderer)
if incompatible_renderers:
glyph_types = ', '.join(type(renderer.glyph).__name__ for renderer in incompatible_renderers)
return "%s glyph type(s) found." % glyph_types
[docs]class PolyEditTool(PolyTool, Drag, Tap):
''' *toolbar icon*: |poly_edit_icon|
The PolyEditTool allows editing the vertices of one or more ``Patches`` or
``MultiLine`` glyphs. Glyphs to be edited are defined via the ``renderers``
property and a renderer for the vertices is set via the ``vertex_renderer``
property (must render a point-like Glyph (a subclass of ``XYGlyph``).
The tool will modify the columns on the data source corresponding to the
``xs`` and ``ys`` values of the glyph. Any additional columns in the data
source will be padded with the declared``empty_value``, when adding a new
point.
The supported actions include:
* Show vertices: Double tap an existing patch or multi-line
* Add vertex: Double tap an existing vertex to select it, the tool will
draw the next point, to add it tap in a new location. To finish editing
and add a point double tap otherwise press the <<esc> key to cancel.
* Move vertex: Drag an existing vertex and let go of the mouse button to
release it.
* Delete vertex: After selecting one or more vertices press <<backspace>>
while the mouse cursor is within the plot area.
.. |poly_edit_icon| image:: /_images/icons/PolyEdit.png
:height: 24px
:alt: Icon of two lines meeting in a vertex with an arrow pointing at it representing the polygon-edit tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
@error(INCOMPATIBLE_POLY_EDIT_RENDERER)
def _check_compatible_renderers(self):
incompatible_renderers = []
for renderer in self.renderers:
if not isinstance(renderer.glyph, (MultiLine, Patches)):
incompatible_renderers.append(renderer)
if incompatible_renderers:
glyph_types = ', '.join(type(renderer.glyph).__name__
for renderer in incompatible_renderers)
return "%s glyph type(s) found." % glyph_types
[docs]class LineEditTool(EditTool, Drag, Tap):
''' *toolbar icon*: |line_edit_icon|
The LineEditTool allows editing the intersection points of one or more ``Line`` glyphs.
Glyphs to be edited are defined via the ``renderers``
property and a renderer for the intersections is set via the ``intersection_renderer``
property (must render a point-like Glyph (a subclass of ``XYGlyph``).
The tool will modify the columns on the data source corresponding to the
``x`` and ``y`` values of the glyph. Any additional columns in the data
source will be padded with the declared``empty_value``, when adding a new
point.
The supported actions include:
* Show intersections: Double tap an existing line
* Move point: Drag an existing point and let go of the mouse button to
release it.
.. |line_edit_icon| image:: /_images/icons/LineEdit.png
:height: 24px
:alt: Icon of a line with a point on it with an arrow pointing at it representing the line-edit tool in the toolbar.
'''
# explicit __init__ to support Init signatures
def __init__(self, *args, **kwargs) -> None:
super().__init__(*args, **kwargs)
intersection_renderer = Instance(GlyphRenderer, help="""
The renderer used to render the intersections of a selected line
""")
dimensions = Enum(Dimensions, default="both", help="""
Which dimensions this edit tool is constrained to act in. By default
the line edit tool allows moving points in any dimension, but can be
configured to only allow horizontal movement across the width of the
plot, or vertical across the height of the plot.
""")
@error(INCOMPATIBLE_LINE_EDIT_INTERSECTION_RENDERER)
def _check_compatible_intersection_renderer(self):
glyph = self.intersection_renderer.glyph
if not isinstance(glyph, LineGlyph):
return "glyph type %s found." % type(glyph).__name__
@error(INCOMPATIBLE_LINE_EDIT_RENDERER)
def _check_compatible_renderers(self):
incompatible_renderers = []
for renderer in self.renderers:
if not isinstance(renderer.glyph, (Line,)):
incompatible_renderers.append(renderer)
if incompatible_renderers:
glyph_types = ', '.join(type(renderer.glyph).__name__
for renderer in incompatible_renderers)
return "%s glyph type(s) found." % glyph_types
#
#-----------------------------------------------------------------------------
# Dev API
#-----------------------------------------------------------------------------
#-----------------------------------------------------------------------------
# Private API
#-----------------------------------------------------------------------------
#-----------------------------------------------------------------------------
# Code
#-----------------------------------------------------------------------------
Tool.register_alias("pan", lambda: PanTool(dimensions="both"))
Tool.register_alias("xpan", lambda: PanTool(dimensions="width"))
Tool.register_alias("ypan", lambda: PanTool(dimensions="height"))
Tool.register_alias("xwheel_pan", lambda: WheelPanTool(dimension="width"))
Tool.register_alias("ywheel_pan", lambda: WheelPanTool(dimension="height"))
Tool.register_alias("wheel_zoom", lambda: WheelZoomTool(dimensions="both"))
Tool.register_alias("xwheel_zoom", lambda: WheelZoomTool(dimensions="width"))
Tool.register_alias("ywheel_zoom", lambda: WheelZoomTool(dimensions="height"))
Tool.register_alias("zoom_in", lambda: ZoomInTool(dimensions="both"))
Tool.register_alias("xzoom_in", lambda: ZoomInTool(dimensions="width"))
Tool.register_alias("yzoom_in", lambda: ZoomInTool(dimensions="height"))
Tool.register_alias("zoom_out", lambda: ZoomOutTool(dimensions="both"))
Tool.register_alias("xzoom_out", lambda: ZoomOutTool(dimensions="width"))
Tool.register_alias("yzoom_out", lambda: ZoomOutTool(dimensions="height"))
Tool.register_alias("click", lambda: TapTool(behavior="inspect"))
Tool.register_alias("tap", lambda: TapTool())
Tool.register_alias("doubletap", lambda: TapTool(gesture="doubletap"))
Tool.register_alias("crosshair", lambda: CrosshairTool())
Tool.register_alias("box_select", lambda: BoxSelectTool())
Tool.register_alias("xbox_select", lambda: BoxSelectTool(dimensions="width"))
Tool.register_alias("ybox_select", lambda: BoxSelectTool(dimensions="height"))
Tool.register_alias("poly_select", lambda: PolySelectTool())
Tool.register_alias("lasso_select", lambda: LassoSelectTool())
Tool.register_alias("box_zoom", lambda: BoxZoomTool(dimensions="both"))
Tool.register_alias("xbox_zoom", lambda: BoxZoomTool(dimensions="width"))
Tool.register_alias("ybox_zoom", lambda: BoxZoomTool(dimensions="height"))
Tool.register_alias("auto_box_zoom", lambda: BoxZoomTool(dimensions="auto"))
Tool.register_alias("save", lambda: SaveTool())
Tool.register_alias("copy", lambda: CopyTool())
Tool.register_alias("undo", lambda: UndoTool())
Tool.register_alias("redo", lambda: RedoTool())
Tool.register_alias("reset", lambda: ResetTool())
Tool.register_alias("help", lambda: HelpTool())
Tool.register_alias("examine", lambda: ExamineTool())
Tool.register_alias("fullscreen", lambda: FullscreenTool())
Tool.register_alias("box_edit", lambda: BoxEditTool())
Tool.register_alias("line_edit", lambda: LineEditTool())
Tool.register_alias("point_draw", lambda: PointDrawTool())
Tool.register_alias("poly_draw", lambda: PolyDrawTool())
Tool.register_alias("poly_edit", lambda: PolyEditTool())
Tool.register_alias("freehand_draw", lambda: FreehandDrawTool())
Tool.register_alias("hover", lambda: HoverTool(tooltips=[
("index", "$index"),
("data (x, y)", "($x, $y)"),
("screen (x, y)", "($sx, $sy)"),
]))