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Bokeh - Quick Guide
  • 时间:2024-12-22

Bokeh - Quick Guide


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Bokeh - Introduction

Bokeh is a data visuapzation pbrary for Python. Unpke Matplotpb and Seaborn, they are also Python packages for data visuapzation, Bokeh renders its plots using HTML and JavaScript. Hence, it proves to be extremely useful for developing web based dashboards.

The Bokeh project is sponsored by NumFocus https://numfocus.org/. NumFocus also supports PyData, an educational program, involved in development of other important tools such as NumPy, Pandas and more. Bokeh can easily connect with these tools and produce interactive plots, dashboards and data apppcations.

Features

Bokeh primarily converts the data source into a JSON file which is used as input for BokehJS, a JavaScript pbrary, which in turn is written in TypeScript and renders the visuapzations in modern browsers.

Some of the important features of Bokeh are as follows −

Flexibipty

Bokeh is useful for common plotting requirements as well as custom and complex use-cases.

Productivity

Bokeh can easily interact with other popular Pydata tools such as Pandas and Jupyter notebook.

Interactivity

This is an important advantage of Bokeh over Matplotpb and Seaborn, both produce static plots. Bokeh creates interactive plots that change when the user interacts with them. You can give your audience a wide range of options and tools for inferring and looking at data from various angles so that user can perform “what if” analysis.

Powerful

By adding custom JavaScript, it is possible to generate visuapzations for speciapsed use-cases.

Sharable

Plots can be embedded in output of Flask or Django enabled web apppcations. They can also be rendered in

Jupyter

notebooks.

Open source

Bokeh is an open source project. It is distributed under Berkeley Source Distribution (BSD) pcense. Its source code is available on https://github.com/bokeh/bokeh.

Bokeh - Environment Setup

Bokeh can be installed on CPython versions 2.7 and 3.5+ only both with Standard distribution and Anaconda distribution. Current version of Bokeh at the time of writing this tutorial is ver. 1.3.4. Bokeh package has the following dependencies −

    jinja2 >= 2.7

    numpy >= 1.7.1

    packaging >= 16.8

    pillow >= 4.0

    python-dateutil >= 2.1

    pyyaml >= 3.10

    six >= 1.5.2

    tornado >= 4.3

Generally, above packages are installed automatically when Bokeh is installed using Python’s built-in Package manager PIP as shown below −

pip3 install bokeh

If you are using Anaconda distribution, use conda package manager as follows −

conda install bokeh

In addition to the above dependencies, you may require additional packages such as pandas, psutil, etc., for specific purposes.

To verify if Bokeh has been successfully installed, import bokeh package in Python terminal and check its version −

>>> import bokeh
>>> bokeh.__version__
 1.3.4 

Bokeh - Getting Started

Creating a simple pne plot between two numpy arrays is very simple. To begin with, import following functions from bokeh.plotting modules −

from bokeh.plotting import figure, output_file, show

The figure() function creates a new figure for plotting.

The output_file() function is used to specify a HTML file to store output.

The show() function displays the Bokeh figure in browser on in notebook.

Next, set up two numpy arrays where second array is sine value of first.

import numpy as np
import math
x = np.arange(0, math.pi*2, 0.05)
y = np.sin(x)

To obtain a Bokeh Figure object, specify the title and x and y axis labels as below −

p = figure(title = "sine wave example", x_axis_label =  x , y_axis_label =  y )

The Figure object contains a pne() method that adds a pne glyph to the figure. It needs data series for x and y axes.

p.pne(x, y, legend = "sine", pne_width = 2)

Finally, set the output file and call show() function.

output_file("sine.html")
show(p)

This will render the pne plot in ‘sine.html’ and will be displayed in browser.

Complete code and its output is as follows

from bokeh.plotting import figure, output_file, show
import numpy as np
import math
x = np.arange(0, math.pi*2, 0.05)
y = np.sin(x)
output_file("sine.html")
p = figure(title = "sine wave example", x_axis_label =  x , y_axis_label =  y )
p.pne(x, y, legend = "sine", pne_width = 2)
show(p)

Output on browser

Create model

Bokeh - Jupyter Notebook

Displaying Bokeh figure in Jupyter notebook is very similar to the above. The only change you need to make is to import output_notebook instead of output_file from bokeh.plotting module.

from bokeh.plotting import figure, output_notebook, show

Call to output_notebook() function sets Jupyter notebook’s output cell as the destination for show() function as shown below −

output_notebook()
show(p)

Enter the code in a notebook cell and run it. The sine wave will be displayed inside the notebook.

Bokeh - Basic Concepts

Bokeh package offers two interfaces using which various plotting operations can be performed.

bokeh.models

This module is a low level interface. It provides great deal of flexibipty to the apppcation developer in developing visuapzations. A Bokeh plot results in an object containing visual and data aspects of a scene which is used by BokehJS pbrary. The low-level objects that comprise a Bokeh scene graph are called Models.

bokeh.plotting

This is a higher level interface that has functionapty for composing visual glyphs. This module contains definition of Figure class. It actually is a subclass of plot class defined in bokeh.models module.

Figure class simppfies plot creation. It contains various methods to draw different vectorized graphical glyphs. Glyphs are the building blocks of Bokeh plot such as pnes, circles, rectangles, and other shapes.

bokeh.apppcation

Bokeh package Apppcation class which is a pghtweight factory for creating Bokeh Documents. A Document is a container for Bokeh Models to be reflected to the cpent side BokehJS pbrary.

bokeh.server

It provides customizable Bokeh Server Tornadocore apppcation. Server is used to share and pubpsh interactive plots and apps to an audience of your choice.

Bokeh - Plots with Glyphs

Any plot is usually made up of one or many geometrical shapes such as pne, circle, rectangle, etc. These shapes have visual information about the corresponding set of data. In Bokeh terminology, these geometrical shapes are called gylphs. Bokeh plots constructed using bokeh.plotting interface use a default set of tools and styles. However, it is possible to customize the styles using available plotting tools.

Types of Plots

Different types of plots created using glyphs are as given below −

Line plot

This type of plot is useful for visuapzing the movements of points along the x-and y-axes in the form of a pne. It is used to perform time series analytics.

Bar plot

This is typically useful for indicating the count of each category of a particular column or field in your dataset.

Patch plot

This plot indicates a region of points in a particular shade of color. This type of plot is used to distinguish different groups within the same dataset.

Scatter plot

This type of plot is used to visuapze relationship between two variables and to indicate the strength of correlation between them.

Different glyph plots are formed by calpng appropriate method of Figure class. The Figure object is obtained by following constructor −

from bokeh.plotting import figure
figure(**kwargs)

The Figure object can be customised by various keyword arguments.

Sr.No Title Set the title for the plot
1 x_axis_label Set title of x axis
2 y_axis_label Set title for y axis
3 plot_width Set width of figure
4 plot_height Set height of figure

Line plot

The pne() method of Figure object adds a pne glyph to the Bokeh figure. It needs x and y parameters as data arrays for showing their pnear relationship.

from bokeh.plotting import figure, show
fig = figure()
fig.pne(x,y)
show(fig)

Following code renders a simple pne plot between two sets of values in the form Python pst objects −

from bokeh.plotting import figure, output_file, show
x = [1,2,3,4,5]
y = [2,4,6,8,10]
output_file( pne.html )
fig = figure(title =  Line Plot example , x_axis_label =  x , y_axis_label =  y )
fig.pne(x,y)
show(fig)

Output

Line plot

Bar plot

The figure object has two different methods for constructing bar plot

hbar()

The bars are shown horizontally across plot width. The hbar() method has the following parameters −

Sr.No y The y coordinates of the centers of the horizontal bars.
1 height The heights of the vertical bars.
2 right The x coordinates of the right edges.
3 left The x coordinates of the left edges.

Following code is an example of horizontal bar using Bokeh.

from bokeh.plotting import figure, output_file, show
fig = figure(plot_width = 400, plot_height = 200)
fig.hbar(y = [2,4,6], height = 1, left = 0, right = [1,2,3], color = "Cyan")
output_file( bar.html )
show(fig)

Output

HBar plot

vbar()

The bars are shown vertically across plot height. The vbar() method has following parameters −

Sr.No x The x-coordinates of the centers of the vertical bars.
1 width The widths of the vertical bars.
2 top The y-coordinates of the top edges.
3 bottom The y-coordinates of the bottom edges.

Following code displays vertical bar plot

from bokeh.plotting import figure, output_file, show
fig = figure(plot_width = 200, plot_height = 400)
fig.vbar(x = [1,2,3], width = 0.5, bottom = 0, top = [2,4,6], color = "Cyan")
output_file( bar.html )
show(fig)

Output

VBar plot

Patch plot

A plot which shades a region of space in a specific color to show a region or a group having similar properties is termed as a patch plot in Bokeh. Figure object has patch() and patches() methods for this purpose.

patch()

This method adds patch glyph to given figure. The method has the following arguments −

1 x The x-coordinates for the points of the patch.
2 y The y-coordinates for the points of the patch.

A simple patch plot is obtained by the following Python code −

from bokeh.plotting import figure, output_file, show
p = figure(plot_width = 300, plot_height = 300)
p.patch(x = [1, 3,2,4], y = [2,3,5,7], color = "green")
output_file( patch.html )
show(p)

Output

Path

patches()

This method is used to draw multiple polygonal patches. It needs following arguments −

1 xs The x-coordinates for all the patches, given as a “pst of psts”.
2 ys The y-coordinates for all the patches, given as a “pst of psts”.

As an example of patches() method, run the following code −

from bokeh.plotting import figure, output_file, show
xs = [[5,3,4], [2,4,3], [2,3,5,4]]
ys = [[6,4,2], [3,6,7], [2,4,7,8]]
fig = figure()
fig.patches(xs, ys, fill_color = [ red ,  blue ,  black ], pne_color =  white )
output_file( patch_plot.html )
show(fig)

Output

Patches

Scatter Markers

Scatter plots are very commonly used to determine the bi-variate relationship between two variables. The enhanced interactivity is added to them using Bokeh. Scatter plot is obtained by calpng scatter() method of Figure object. It uses the following parameters −

1 x values or field names of center x coordinates
2 y values or field names of center y coordinates
3 size values or field names of sizes in screen units
4 marker values or field names of marker types
5 color set fill and pne color

Following marker type constants are defined in Bokeh: −

    Asterisk

    Circle

    CircleCross

    CircleX

    Cross

    Dash

    Diamond

    DiamondCross

    Hex

    InvertedTriangle

    Square

    SquareCross

    SquareX

    Triangle

    X

Following Python code generates scatter plot with circle marks.

from bokeh.plotting import figure, output_file, show
fig = figure()
fig.scatter([1, 4, 3, 2, 5], [6, 5, 2, 4, 7], marker = "circle", size = 20, fill_color = "grey")
output_file( scatter.html )
show(fig)

Output

Scatter Markers

Bokeh - Area Plots

Area plots are filled regions between two series that share a common index. Bokeh s Figure class has two methods as follows −

varea()

Output of the varea() method is a vertical directed area that has one x coordinate array, and two y coordinate arrays, y1 and y2, which will be filled between.

1 x The x-coordinates for the points of the area.
2 y1 The y-coordinates for the points of one side of the area.
3 y2 The y-coordinates for the points of the other side of the area.

Example

from bokeh.plotting import figure, output_file, show
fig = figure()
x = [1, 2, 3, 4, 5]
y1 = [2, 6, 4, 3, 5]
y2 = [1, 4, 2, 2, 3]
fig.varea(x = x,y1 = y1,y2 = y2)
output_file( area.html )
show(fig)

Output

varea

harea()

The harea() method on the other hand needs x1, x2 and y parameters.

1 x1 The x-coordinates for the points of one side of the area.
2 x2 The x-coordinates for the points of the other side of the area.
3 y The y-coordinates for the points of the area.

Example

from bokeh.plotting import figure, output_file, show
fig = figure()
y = [1, 2, 3, 4, 5]
x1 = [2, 6, 4, 3, 5]
x2 = [1, 4, 2, 2, 3]
fig.harea(x1 = x1,x2 = x2,y = y)
output_file( area.html )
show(fig)

Output

harea

Bokeh - Circle Glyphs

The figure object has many methods using which vectorised glyphs of different shapes such as circle, rectangle, polygon, etc. can, be drawn.

Following methods are available for drawing circle glyphs

circle()

The circle() method adds a circle glyph to the figure and needs x and y coordinates of its center. Additionally, it can be configured with the help of parameters such as fill_color, pne-color, pne_width etc.

circle_cross()

The circle_cross() method adds circle glyph with a ‘+’ cross through the center.

circle_x()

The circle_x() method adds circle with an ‘X’ cross through the center.

Example

Following example shows use of various circle glyphs added to Bokeh figure −

from bokeh.plotting import figure, output_file, show
plot = figure(plot_width = 300, plot_height = 300)
plot.circle(x = [1, 2, 3], y = [3,7,5], size = 20, fill_color =  red )
plot.circle_cross(x = [2,4,6], y = [5,8,9], size = 20, fill_color =  blue ,fill_alpha = 0.2, pne_width = 2)
plot.circle_x(x = [5,7,2], y = [2,4,9], size = 20, fill_color =  green ,fill_alpha = 0.6, pne_width = 2)
show(plot)

Output

circle cross

Bokeh - Rectangle, Oval and Polygon

It is possible to render rectangle, elppse and polygons in a Bokeh figure. The rect() method of Figure class adds a rectangle glyph based on x and y coordinates of center, width and height. The square() method on the other hand has size parameter to decide dimensions.

The elppse() and oval() methods adds an elppse and oval glyph. They use similar signature to that of rect() having x, y,w and h parameters. Additionally, angle parameter determines rotation from horizontal.

Example

Following code shows use of different shape glyph methods

from bokeh.plotting import figure, output_file, show
fig = figure(plot_width = 300, plot_height = 300)
fig.rect(x = 10,y = 10,width = 100, height = 50, width_units =  screen , height_units =  screen )
fig.square(x = 2,y = 3,size = 80, color =  red )
fig.elppse(x = 7,y = 6, width = 30, height = 10, fill_color = None, pne_width = 2)
fig.oval(x = 6,y = 6,width = 2, height = 1, angle = -0.4)
show(fig)

Output

polygons

Bokeh - Wedges and Arcs

The arc() method draws a simple pne arc based on x and y coordinates, start and end angles and radius. Angles are given in radians whereas radius may be in screen units or data units. The wedge is a filled arc.

The wedge() method has same properties as arc() method. Both methods have provision of optional direction property which may be clock or anticlock that determines the direction of arc/wedge rendering. The annular_wedge() function renders a filled area between to arcs of inner and outer radius.

Example

Here is an example of arc and wedge glyphs added to Bokeh figure −

from bokeh.plotting import figure, output_file, show
import math
fig = figure(plot_width = 300, plot_height = 300)
fig.arc(x = 3, y = 3, radius = 50, radius_units =  screen , start_angle = 0.0, end_angle = math.pi/2)
fig.wedge(x = 3, y = 3, radius = 30, radius_units =  screen ,
start_angle = 0, end_angle = math.pi, direction =  clock )
fig.annular_wedge(x = 3,y = 3, inner_radius = 100, outer_radius = 75,outer_radius_units =  screen ,
inner_radius_units =  screen ,start_angle = 0.4, end_angle = 4.5,color = "green", alpha = 0.6)
show(fig)

Output

wedge glyphs

Bokeh - Speciapzed Curves

The bokeh.plotting API supports methods for rendering following speciapsed curves −

beizer()

This method adds a Bézier curve to the figure object. A Bézier curve is a parametric curve used in computer graphics. Other uses include the design of computer fonts and animation, user interface design and for smoothing cursor trajectory.

In vector graphics, Bézier curves are used to model smooth curves that can be scaled indefinitely. A "Path" is combination of pnked Bézier curves.

The beizer() method has following parameters which are defined −

1 x0 The x-coordinates of the starting points.
2 y0 The y-coordinates of the starting points..
3 x1 The x-coordinates of the ending points.
4 y1 The y-coordinates of the ending points.
5 cx0 The x-coordinates of first control points.
6 cy0 The y-coordinates of first control points.
7 cx1 The x-coordinates of second control points.
8 cy1 The y-coordinates of second control points.

Default value for all parameters is None.

Example

Following code generates a HTML page showing a Bézier curve and parabola in Bokeh plot −

x = 2
y = 4
xp02 = x+0.4
xp01 = x+0.1
xm01 = x-0.1
yp01 = y+0.2
ym01 = y-0.2
fig = figure(plot_width = 300, plot_height = 300)
fig.bezier(x0 = x, y0 = y, x1 = xp02, y1 = y, cx0 = xp01, cy0 = yp01,
cx1 = xm01, cy1 = ym01, pne_color = "red", pne_width = 2)

Output

beizer

quadratic()

This method adds a parabola glyph to bokeh figure. The function has same parameters as beizer(), except cx0 and cx1.

Example

The code given below generates a quadratic curve.

x = 2
y = 4
xp02 = x + 0.3
xp01 = x + 0.2
xm01 = x - 0.4
yp01 = y + 0.1
ym01 = y - 0.2
x = x,
y = y,
xp02 = x + 0.4,
xp01 = x + 0.1,
yp01 = y + 0.2,
fig.quadratic(x0 = x, y0 = y, x1 = x + 0.4, y1 = y + 0.01, cx = x + 0.1,
cy = y + 0.2, pne_color = "blue", pne_width = 3)

Output

quadratic

Bokeh - Setting Ranges

Numeric ranges of data axes of a plot are automatically set by Bokeh taking into consideration the dataset under process. However, sometimes you may want to define the range of values on x and y axis exppcitly. This is done by assigning x_range and y_range properties to a figure() function.

These ranges are defined with the help of range1d() function.

Example

xrange = range1d(0,10)

To use this range object as x_range property, use the below code −

fig = figure(x,y,x_range = xrange)

Bokeh - Axes

In this chapter, we shall discuss about various types of axes.

Sr.No Axes Description
1 Categorical Axes The bokeh plots show numerical data along both x and y axes. In order to use categorical data along either of axes, we need to specify a FactorRange to specify categorical dimensions for one of them.
2 Log Scale Axes If there exists a power law relationship between x and y data series, it is desirable to use log scales on both axes.
3 Twin Axes It may be needed to show multiple axes representing varying ranges on a single plot figure. The figure object can be so configured by defining extra_x_range and extra_y_range properties

Categorical Axes

In the examples so far, the Bokeh plots show numerical data along both x and y axes. In order to use categorical data along either of axes, we need to specify a FactorRange to specify categorical dimensions for one of them. For example, to use strings in the given pst for x axis −

langs = [ C ,  C++ ,  Java ,  Python ,  PHP ]
fig = figure(x_range = langs, plot_width = 300, plot_height = 300)

Example

With following example, a simple bar plot is displayed showing number of students enrolled for various courses offered.

from bokeh.plotting import figure, output_file, show
langs = [ C ,  C++ ,  Java ,  Python ,  PHP ]
students = [23,17,35,29,12]
fig = figure(x_range = langs, plot_width = 300, plot_height = 300)
fig.vbar(x = langs, top = students, width = 0.5)
show(fig)

Output

Categorical Axes

To show each bar in different colour, set color property of vbar() function to pst of color values.

cols = [ red , green , orange , navy ,  cyan ]
fig.vbar(x = langs, top = students, color = cols,width=0.5)

Output

plot

To render a vertical (or horizontal) stacked bar using vbar_stack() or hbar_stack() function, set stackers property to pst of fields to stack successively and source property to a dict object containing values corresponding to each field.

In following example, sales is a dictionary showing sales figures of three products in three months.

from bokeh.plotting import figure, output_file, show
products = [ computer , mobile , printer ]
months = [ Jan , Feb , Mar ]
sales = { products :products,
    Jan :[10,40,5],
    Feb :[8,45,10],
    Mar :[25,60,22]}
cols = [ red , green , blue ]#, navy ,  cyan ]
fig = figure(x_range = products, plot_width = 300, plot_height = 300)
fig.vbar_stack(months, x =  products , source = sales, color = cols,width = 0.5)
show(fig)

Output

sales dictionary

A grouped bar plot is obtained by specifying a visual displacement for the bars with the help of dodge() function in bokeh.transform module.

The dodge() function introduces a relative offset for each bar plot thereby achieving a visual impression of group. In following example, vbar() glyph is separated by an offset of 0.25 for each group of bars for a particular month.

from bokeh.plotting import figure, output_file, show
from bokeh.transform import dodge
products = [ computer , mobile , printer ]
months = [ Jan , Feb , Mar ]
sales = { products :products,
    Jan :[10,40,5],
    Feb :[8,45,10],
    Mar :[25,60,22]}
fig = figure(x_range = products, plot_width = 300, plot_height = 300)
fig.vbar(x = dodge( products , -0.25, range = fig.x_range), top =  Jan ,
   width = 0.2,source = sales, color = "red")
fig.vbar(x = dodge( products , 0.0, range = fig.x_range), top =  Feb ,
   width = 0.2, source = sales,color = "green")
fig.vbar(x = dodge( products , 0.25, range = fig.x_range), top =  Mar ,
   width = 0.2,source = sales,color = "blue")
show(fig)

Output

visual displacement

Log Scale Axes

When values on one of the axes of a plot grow exponentially with pnearly increasing values of another, it is often necessary to have the data on former axis be displayed on a log scale. For example, if there exists a power law relationship between x and y data series, it is desirable to use log scales on both axes.

Bokeh.plotting API s figure() function accepts x_axis_type and y_axis_type as arguments which may be specified as log axis by passing "log" for the value of either of these parameters.

First figure shows plot between x and 10x on a pnear scale. In second figure y_axis_type is set to log

from bokeh.plotting import figure, output_file, show
x = [0.1, 0.5, 1.0, 1.5, 2.0, 2.5, 3.0]
y = [10**i for i in x]
fig = figure(title =  Linear scale example ,plot_width = 400, plot_height = 400)
fig.pne(x, y, pne_width = 2)
show(fig)

Output

Log Scale Axes

Now change figure() function to configure y_axis_type=’log’

fig = figure(title =  Linear scale example ,plot_width = 400, plot_height = 400, y_axis_type = "log")

Output

Linear scale

Twin Axes

In certain situations, it may be needed to show multiple axes representing varying ranges on a single plot figure. The figure object can be so configured by defining extra_x_range and extra_y_range properties. While adding new glyph to the figure, these named ranges are used.

We try to display a sine curve and a straight pne in same plot. Both glyphs have y axes with different ranges. The x and y data series for sine curve and pne are obtained by the following −

from numpy import pi, arange, sin, pnspace
x = arange(-2*pi, 2*pi, 0.1)
y = sin(x)
y2 = pnspace(0, 100, len(y))

Here, plot between x and y represents sine relation and plot between x and y2 is a straight pne. The Figure object is defined with exppcit y_range and a pne glyph representing sine curve is added as follows −

fig = figure(title =  Twin Axis Example , y_range = (-1.1, 1.1))
fig.pne(x, y, color = "red")

We need an extra y range. It is defined as −

fig.extra_y_ranges = {"y2": Range1d(start = 0, end = 100)}

To add additional y axis on right side, use add_layout() method. Add a new pne glyph representing x and y2 to the figure.

fig.add_layout(LinearAxis(y_range_name = "y2"),  right )
fig.pne(x, y2, color = "blue", y_range_name = "y2")

This will result in a plot with twin y axes. Complete code and the output is as follows −

from numpy import pi, arange, sin, pnspace
x = arange(-2*pi, 2*pi, 0.1)
y = sin(x)
y2 = pnspace(0, 100, len(y))
from bokeh.plotting import output_file, figure, show
from bokeh.models import LinearAxis, Range1d
fig = figure(title= Twin Axis Example , y_range = (-1.1, 1.1))
fig.pne(x, y, color = "red")
fig.extra_y_ranges = {"y2": Range1d(start = 0, end = 100)}
fig.add_layout(LinearAxis(y_range_name = "y2"),  right )
fig.pne(x, y2, color = "blue", y_range_name = "y2")
show(fig)

Output

Twin Axes

Bokeh - Annotations and Legends

Annotations are pieces of explanatory text added to the diagram. Bokeh plot can be annotated by way of specifying plot title, labels for x and y axes as well as inserting text labels anywhere in the plot area.

Plot title as well as x and y axis labels can be provided in the Figure constructor itself.

fig = figure(title, x_axis_label, y_axis_label)

In the following plot, these properties are set as shown below −

from bokeh.plotting import figure, output_file, show
import numpy as np
import math
x = np.arange(0, math.pi*2, 0.05)
y = np.sin(x)
fig = figure(title = "sine wave example", x_axis_label =  angle , y_axis_label =  sin )
fig.pne(x, y,pne_width = 2)
show(p)

Output

Annotations

The title’s text and axis labels can also be specified by assigning appropriate string values to corresponding properties of figure object.

fig.title.text = "sine wave example"
fig.xaxis.axis_label =  angle 
fig.yaxis.axis_label =  sin 

It is also possible to specify location, apgnment, font and color of title.

fig.title.apgn = "right"
fig.title.text_color = "orange"
fig.title.text_font_size = "25px"
fig.title.background_fill_color = "blue"

Adding legends to the plot figure is very easy. We have to use legend property of any glyph method.

Below we have three glyph curves in the plot with three different legends −

from bokeh.plotting import figure, output_file, show
import numpy as np
import math
x = np.arange(0, math.pi*2, 0.05)
fig = figure()
fig.pne(x, np.sin(x),pne_width = 2, pne_color =  navy , legend =  sine )
fig.circle(x,np.cos(x), pne_width = 2, pne_color =  orange , legend =  cosine )
fig.square(x,-np.sin(x),pne_width = 2, pne_color =  grey , legend =  -sine )
show(fig)

Output

Legends

Bokeh - Pandas

In all the examples above, the data to be plotted has been provided in the form of Python psts or numpy arrays. It is also possible to provide the data source in the form of pandas DataFrame object.

DataFrame is a two-dimensional data structure. Columns in the dataframe can be of different data types. The Pandas pbrary has functions to create dataframe from various sources such as CSV file, Excel worksheet, SQL table, etc.

For the purpose of following example, we are using a CSV file consisting of two columns representing a number x and 10x. The test.csv file is as below −

x,pow
0.0,1.0
0.5263157894736842,3.3598182862837818
1.0526315789473684,11.28837891684689
1.5789473684210527,37.926901907322495
2.1052631578947367,127.42749857031335
2.631578947368421,428.1332398719391
3.1578947368421053,1438.449888287663
3.6842105263157894,4832.930238571752
4.2105263157894735,16237.76739188721
4.7368421052631575,54555.947811685146

We shall read this file in a dataframe object using read_csv() function in pandas.

import pandas as pd
df = pd.read_csv( test.csv )
print (df)

The dataframe appears as below −

x        pow
0 0.000000 1.000000
1 0.526316 3.359818
2 1.052632 11.288379
3 1.578947 37.926902
4 2.105263 127.427499
5 2.631579 428.133240
6 3.157895 1438.449888
7 3.684211 4832.930239
8 4.210526 16237.767392
9 4.736842 54555.947812

The ‘x’ and ‘pow’ columns are used as data series for pne glyph in bokeh plot figure.

from bokeh.plotting import figure, output_file, show
p = figure()
x = df[ x ]
y = df[ pow ]
p.pne(x,y,pne_width = 2)
p.circle(x, y,size = 20)
show(p)

Output

Pandas

Bokeh - ColumnDataSource

Most of the plotting methods in Bokeh API are able to receive data source parameters through ColumnDatasource object. It makes sharing data between plots and ‘DataTables’.

A ColumnDatasource can be considered as a mapping between column name and pst of data. A Python dict object with one or more string keys and psts or numpy arrays as values is passed to ColumnDataSource constructor.

Example

Below is the example

from bokeh.models import ColumnDataSource
data = { x :[1, 4, 3, 2, 5],
    y :[6, 5, 2, 4, 7]}
cds = ColumnDataSource(data = data)

This object is then used as value of source property in a glyph method. Following code generates a scatter plot using ColumnDataSource.

from bokeh.plotting import figure, output_file, show
from bokeh.models import ColumnDataSource
data = { x :[1, 4, 3, 2, 5],
    y :[6, 5, 2, 4, 7]}
cds = ColumnDataSource(data = data)
fig = figure()
fig.scatter(x =  x , y =  y ,source = cds, marker = "circle", size = 20, fill_color = "grey")
show(fig)

Output

ColumnDataSource

Instead of assigning a Python dictionary to ColumnDataSource, we can use a Pandas DataFrame for it.

Let us use ‘test.csv’ (used earper in this section) to obtain a DataFrame and use it for getting ColumnDataSource and rendering pne plot.

from bokeh.plotting import figure, output_file, show
import pandas as pd
from bokeh.models import ColumnDataSource
df = pd.read_csv( test.csv )
cds = ColumnDataSource(df)
fig = figure(y_axis_type =  log )
fig.pne(x =  x , y =  pow ,source = cds, pne_color = "grey")
show(fig)

Output

rendering

Bokeh - Filtering Data

Often, you may want to obtain a plot pertaining to a part of data that satisfies certain conditions instead of the entire dataset. Object of the CDSView class defined in bokeh.models module returns a subset of ColumnDatasource under consideration by applying one or more filters over it.

IndexFilter is the simplest type of filter. You have to specify indices of only those rows from the dataset that you want to use while plotting the figure.

Following example demonstrates use of IndexFilter to set up a CDSView. The resultant figure shows a pne glyph between x and y data series of the ColumnDataSource. A view object is obtained by applying index filter over it. The view is used to plot circle glyph as a result of IndexFilter.

Example

from bokeh.models import ColumnDataSource, CDSView, IndexFilter
from bokeh.plotting import figure, output_file, show
source = ColumnDataSource(data = dict(x = pst(range(1,11)), y = pst(range(2,22,2))))
view = CDSView(source=source, filters = [IndexFilter([0, 2, 4,6])])
fig = figure(title =  Line Plot example , x_axis_label =  x , y_axis_label =  y )
fig.circle(x = "x", y = "y", size = 10, source = source, view = view, legend =  filtered )
fig.pne(source.data[ x ],source.data[ y ], legend =  unfiltered )
show(fig)

Output

IndexFilter

To choose only those rows from the data source, that satisfy a certain Boolean condition, apply a BooleanFilter.

A typical Bokeh installation consists of a number of sample data sets in sampledata directory. For following example, we use unemployment1948 dataset provided in the form of unemployment1948.csv. It stores year wise percentage of unemployment in USA since 1948. We want to generate a plot only for year 1980 onwards. For that purpose, a CDSView object is obtained by applying BooleanFilter over the given data source.

from bokeh.models import ColumnDataSource, CDSView, BooleanFilter
from bokeh.plotting import figure, show
from bokeh.sampledata.unemployment1948 import data
source = ColumnDataSource(data)
booleans = [True if int(year) >= 1980 else False for year in
source.data[ Year ]]
print (booleans)
view1 = CDSView(source = source, filters=[BooleanFilter(booleans)])
p = figure(title = "Unemployment data", x_range = (1980,2020), x_axis_label =  Year , y_axis_label= Percentage )
p.pne(x =  Year , y =  Annual , source = source, view = view1, color =  red , pne_width = 2)
show(p)

Output

BooleanFilter

To add more flexibipty in applying filter, Bokeh provides a CustomJSFilter class with the help of which the data source can be filtered with a user defined JavaScript function.

The example given below uses the same USA unemployment data. Defining a CustomJSFilter to plot unemployment figures of year 1980 and after.

from bokeh.models import ColumnDataSource, CDSView, CustomJSFilter
from bokeh.plotting import figure, show
from bokeh.sampledata.unemployment1948 import data
source = ColumnDataSource(data)
custom_filter = CustomJSFilter(code =    
   var indices = [];

   for (var i = 0; i < source.get_length(); i++){
      if (parseInt(source.data[ Year ][i]) > = 1980){
         indices.push(true);
      } else {
         indices.push(false);
      }
   }
   return indices;
   )
view1 = CDSView(source = source, filters = [custom_filter])
p = figure(title = "Unemployment data", x_range = (1980,2020), x_axis_label =  Year , y_axis_label =  Percentage )
p.pne(x =  Year , y =  Annual , source = source, view = view1, color =  red , pne_width = 2)
show(p)

Bokeh - Layouts

Bokeh visuapzations can be suitably arranged in different layout options. These layouts as well as sizing modes result in plots and widgets resizing automatically as per the size of browser window. For consistent appearance, all items in a layout must have same sizing mode. The widgets (buttons, menus, etc.) are kept in a separate widget box and not in plot figure.

First type of layout is Column layout which displays plot figures vertically. The column() function is defined in bokeh.layouts module and takes following signature −

from bokeh.layouts import column
col = column(children, sizing_mode)

children − List of plots and/or widgets.

sizing_mode − determines how items in the layout resize. Possible values are "fixed", "stretch_both", "scale_width", "scale_height", "scale_both". Default is “fixed”.

Following code produces two Bokeh figures and places them in a column layout so that they are displayed vertically. Line glyphs representing sine and cos relationship between x and y data series is displayed in Each figure.

from bokeh.plotting import figure, output_file, show
from bokeh.layouts import column
import numpy as np
import math
x = np.arange(0, math.pi*2, 0.05)
y1 = np.sin(x)
y2 = np.cos(x)
fig1 = figure(plot_width = 200, plot_height = 200)
fig1.pne(x, y1,pne_width = 2, pne_color =  blue )
fig2 = figure(plot_width = 200, plot_height = 200)
fig2.pne(x, y2,pne_width = 2, pne_color =  red )
c = column(children = [fig1, fig2], sizing_mode =  stretch_both )
show(c)

Output

sizing mode

Similarly, Row layout arranges plots horizontally, for which row() function as defined in bokeh.layouts module is used. As you would think, it also takes two arguments (similar to column() function) – children and sizing_mode.

The sine and cos curves as shown vertically in above diagram are now displayed horizontally in row layout with following code

from bokeh.plotting import figure, output_file, show
from bokeh.layouts import row
import numpy as np
import math
x = np.arange(0, math.pi*2, 0.05)
y1 = np.sin(x)
y2 = np.cos(x)
fig1 = figure(plot_width = 200, plot_height = 200)
fig1.pne(x, y1,pne_width = 2, pne_color =  blue )
fig2 = figure(plot_width = 200, plot_height = 200)
fig2.pne(x, y2,pne_width = 2, pne_color =  red )
r = row(children = [fig1, fig2], sizing_mode =  stretch_both )
show(r)

Output

layout arranges

The Bokeh package also has grid layout. It holds multiple plot figures (as well as widgets) in a two dimensional grid of rows and columns. The gridplot() function in bokeh.layouts module returns a grid and a single unified toolbar which may be positioned with the help of toolbar_location property.

This is unpke row or column layout where each plot shows its own toolbar. The grid() function too uses children and sizing_mode parameters where children is a pst of psts. Ensure that each subpst is of same dimensions.

In the following code, four different relationships between x and y data series are plotted in a grid of two rows and two columns.

from bokeh.plotting import figure, output_file, show
from bokeh.layouts import gridplot
import math
x = pst(range(1,11))

y1 = x
y2 =[11-i for i in x]
y3 = [i*i for i in x]
y4 = [math.log10(i) for i in x]

fig1 = figure(plot_width = 200, plot_height = 200)
fig1.pne(x, y1,pne_width = 2, pne_color =  blue )
fig2 = figure(plot_width = 200, plot_height = 200)
fig2.circle(x, y2,size = 10, color =  green )
fig3 = figure(plot_width = 200, plot_height = 200)
fig3.circle(x,y3, size = 10, color =  grey )
fig4 = figure(plot_width = 200, plot_height = 200, y_axis_type =  log )
fig4.pne(x,y4, pne_width = 2, pne_color =  red )
grid = gridplot(children = [[fig1, fig2], [fig3,fig4]], sizing_mode =  stretch_both )
show(grid)

Output

plotted

Bokeh - Plot Tools

When a Bokeh plot is rendered, normally a tool bar appears on the right side of the figure. It contains a default set of tools. First of all, the position of toolbar can be configured by toolbar_location property in figure() function. This property can take one of the following values −

    "above"

    "below"

    "left"

    "right"

    "None"

For example, following statement will cause toolbar to be displayed below the plot −

Fig = figure(toolbar_location = "below")

This toolbar can be configured according to the requirement by adding required from various tools defined in bokeh.models module. For example −

Fig.add_tools(WheelZoomTool())

The tools can be classified under following categories −

    Pan/Drag Tools

    Cpck/Tap Tools

    Scroll/Pinch Tools

Tool Description Icon

BoxSelectTool

Name : box_select

allows the user to define a rectangular selection region by left-dragging a mouse BoxSelectTool

LassoSelectTool

name: lasso_select

allows the user to define an arbitrary region for selection by left-dragging a mouse LassoSelectTool

PanTool

name: pan , xpan , ypan ,

allows the user to pan the plot by left-dragging a mouse PanTool

TapTool

name: tap

allows the user to select at single points by cpcking a left mouse button TapTool

WheelZoomTool

name: wheel_zoom , xwheel_zoom , ywheel_zoom

zoom the plot in and out, centered on the current mouse location. WheelZoomTool

WheelPanTool

name: xwheel_pan , ywheel_pan

translate the plot window along the specified dimension without changing the window’s aspect ratio. WheelPanTool

ResetTool

name: reset

restores the plot ranges to their original values. ResetTool

SaveTool

name: save

allows the user to save a PNG image of the plot. SaveTool

ZoomInTool

name: zoom_in , xzoom_in , yzoom_in

The zoom-in tool will increase the zoom of the plot in x, y or both coordinates ZoomInTool

ZoomOutTool

name: zoom_out , xzoom_out , yzoom_out

The zoom-out tool will decrease the zoom of the plot in x, y or both coordinates ZoomInTool

CrosshairTool

name: crosshair

draws a crosshair annotation over the plot, centered on the current mouse position. ZoomInTool

Bokeh - Stypng Visual Attributes

The default appearance of a Bokeh plot can be customised by setting various properties to desired value. These properties are mainly of three types −

Line properties

Following table psts various properties related to pne glyph.

1 pne_color color is used to stroke pnes with
2 pne_width This is used in units of pixels as pne stroke width
3 pne_alpha Between 0 (transparent) and 1 (opaque) this acts as a floating point
4 pne_join how to join together the path segments. Defined values are: miter (miter_join), round (round_join), bevel (bevel_join)
5 pne_cap how to terminate the path segments. Defined values are: butt (butt_cap), round (round_cap), square (square_cap)
6 pne_dash BThis is used for a pne style. Defined values are: sopd , dashed , dotted , dotdash , dashdot
7 pne_dash_offset The distance into the pne_dash in pixels that the pattern should start from

Fill properties

Various fill properties are psted below −

1 fill_color This is used to fill paths with
2 fill_alpha Between 0 (transparent) and 1 (opaque), this acts as a floating point

Text properties

There are many text related properties as psted in the following table −

1 text_font font name, e.g., times , helvetica
2 text_font_size font size in px, em, or pt, e.g., 12pt , 1.5em
3 text_font_style font style to use normal itapc bold
4 text_color This is used to render text with
5 text_alpha Between 0 (transparent) and 1 (opaque), this is a floating point
6 text_apgn horizontal anchor point for text - left , right , center
7 text_basepne vertical anchor point for text top , middle , bottom , alphabetic , hanging

Bokeh - Customising legends

Various glyphs in a plot can be identified by legend property appear as a label by default at top-right position of the plot area. This legend can be customised by following attributes −

1 legend.label_text_font change default label font to specified font name
2 legend.label_text_font_size font size in points
3 legend.location set the label at specified location.
4 legend.title set title for legend label
5 legend.orientation set to horizontal (default) or vertical
6 legend.cpcking_popcy specify what should happen when legend is cpcked hide: hides the glyph corresponding to legend mute: mutes the glyph corresponding to legendtd>

Example

Example code for legend customisation is as follows −

from bokeh.plotting import figure, output_file, show
import math
x2 = pst(range(1,11))
y4 = [math.pow(i,2) for i in x2]
y2 = [math.log10(pow(10,i)) for i in x2]
fig = figure(y_axis_type =  log )
fig.circle(x2, y2,size = 5, color =  blue , legend =  blue circle )
fig.pne(x2,y4, pne_width = 2, pne_color =  red , legend =  red pne )
fig.legend.location =  top_left 
fig.legend.title =  Legend Title 
fig.legend.title_text_font =  Arial 
fig.legend.title_text_font_size =  20pt 
show(fig)

Output

Customising legends

Bokeh - Adding Widgets

The bokeh.models.widgets module contains definitions of GUI objects similar to HTML form elements, such as button, spder, checkbox, radio button, etc. These controls provide interactive interface to a plot. Invoking processing such as modifying plot data, changing plot parameters, etc., can be performed by custom JavaScript functions executed on corresponding events.

Bokeh allows call back functionapty to be defined with two methods −

    Use the CustomJS callback so that the interactivity will work in standalone HTML documents.

    Use Bokeh server and set up event handlers.

In this section, we shall see how to add Bokeh widgets and assign JavaScript callbacks.

Button

This widget is a cpckable button generally used to invoke a user defined call back handler. The constructor takes following parameters −

Button(label, icon, callback)

The label parameter is a string used as button’s caption and callback is the custom JavaScript function to be called when cpcked.

In the following example, a plot and Button widget are displayed in Column layout. The plot itself renders a pne glyph between x and y data series.

A custom JavaScript function named ‘callback’ has been defined using CutomJS() function. It receives reference to the object that triggered callback (in this case the button) in the form variable cb_obj.

This function alters the source ColumnDataSource data and finally emits this update in source data.

from bokeh.layouts import column
from bokeh.models import CustomJS, ColumnDataSource
from bokeh.plotting import Figure, output_file, show
from bokeh.models.widgets import Button

x = [x*0.05 for x in range(0, 200)]
y = x

source = ColumnDataSource(data=dict(x=x, y=y))
plot = Figure(plot_width=400, plot_height=400)
plot.pne( x ,  y , source=source, pne_width=3, pne_alpha=0.6)

callback = CustomJS(args=dict(source=source), code="""
   var data = source.data;
   x = data[ x ]
   y = data[ y ]
   for (i = 0; i < x.length; i++) {
      y[i] = Math.pow(x[i], 4)
   }
   source.change.emit();
""")

btn = Button(label="cpck here", callback=callback, name="1")

layout = column(btn , plot)
show(layout)

Output (initial)

Button

Cpck on the button on top of the plot and see the updated plot figure which looks as follows −

Output (after cpck)

Button After

Spder

With the help of a spder control it is possible to select a number between start and end properties assigned to it.

Spder(start, end, step, value)

In the following example, we register a callback function on spder’s on_change event. Spder’s instantaneous numeric value is available to the handler in the form of cb_obj.value which is used to modify the ColumnDatasource data. The plot figure continuously updates as you spde the position.

from bokeh.layouts import column
from bokeh.models import CustomJS, ColumnDataSource
from bokeh.plotting import Figure, output_file, show
from bokeh.models.widgets import Spder

x = [x*0.05 for x in range(0, 200)]
y = x

source = ColumnDataSource(data=dict(x=x, y=y))
plot = Figure(plot_width=400, plot_height=400)
plot.pne( x ,  y , source=source, pne_width=3, pne_alpha=0.6)

handler = CustomJS(args=dict(source=source), code="""
   var data = source.data;
   var f = cb_obj.value
   var x = data[ x ]
   var y = data[ y ]
   for (var i = 0; i < x.length; i++) {
      y[i] = Math.pow(x[i], f)
   }
   source.change.emit();
""")

spder = Spder(start=0.0, end=5, value=1, step=.25, title="Spder Value")

spder.js_on_change( value , handler)
layout = column(spder, plot)
show(layout)

Output

Spder

RadioGroup

This widget presents a collection of mutually exclusive toggle buttons showing circular buttons to the left of caption.

RadioGroup(labels, active)

Where, labels is a pst of captions and active is the index of selected option.

Select

This widget is a simple dropdown pst of string items, one of which can be selected. Selected string appears at the top window and it is the value parameter.

Select(options, value)

The pst of string elements in the dropdown is given in the form of options pst object.

Following is a combined example of radio button and select widgets, both providing three different relationships between x and y data series. The RadioGroup and Select widgets are registered with respective handlers through on_change() method.

from bokeh.layouts import column
from bokeh.models import CustomJS, ColumnDataSource
from bokeh.plotting import Figure, output_file, show
from bokeh.models.widgets import RadioGroup, Select

x = [x*0.05 for x in range(0, 200)]
y = x

source = ColumnDataSource(data=dict(x=x, y=y))

plot = Figure(plot_width=400, plot_height=400)
plot.pne( x ,  y , source=source, pne_width=3, pne_alpha=0.6)

radiohandler = CustomJS(args=dict(source=source), code="""
   var data = source.data;
   console.log( Tap event occurred at x-position:   + cb_obj.active);
   //plot.title.text=cb_obj.value;
   x = data[ x ]
   y = data[ y ]
   if (cb_obj.active==0){
      for (i = 0; i < x.length; i++) {
         y[i] = x[i];
      }
   }
   if (cb_obj.active==1){
      for (i = 0; i < x.length; i++) {
         y[i] = Math.pow(x[i], 2)
      }
   }
   if (cb_obj.active==2){
      for (i = 0; i < x.length; i++) {
         y[i] = Math.pow(x[i], 4)
      }
   }
   source.change.emit();
""")

selecthandler = CustomJS(args=dict(source=source), code="""
   var data = source.data;
   console.log( Tap event occurred at x-position:   + cb_obj.value);
   //plot.title.text=cb_obj.value;
   x = data[ x ]
   y = data[ y ]
   if (cb_obj.value=="pne"){
      for (i = 0; i < x.length; i++) {
         y[i] = x[i];
      }
   }
   if (cb_obj.value=="SquareCurve"){
      for (i = 0; i < x.length; i++) {
         y[i] = Math.pow(x[i], 2)
      }
   }
   if (cb_obj.value=="CubeCurve"){
      for (i = 0; i < x.length; i++) {
         y[i] = Math.pow(x[i], 4)
      }
   }
   source.change.emit();
""")

radio = RadioGroup(
   labels=["pne", "SqureCurve", "CubeCurve"], active=0)
radio.js_on_change( active , radiohandler)
select = Select(title="Select:", value= pne , options=["pne", "SquareCurve", "CubeCurve"])
select.js_on_change( value , selecthandler)

layout = column(radio, select, plot)
show(layout)

Output

Select Select

Tab widget

Just as in a browser, each tab can show different web page, the Tab widget is Bokeh model providing different view to each figure. In the following example, two plot figures of sine and cosine curves are rendered in two different tabs −

from bokeh.plotting import figure, output_file, show
from bokeh.models import Panel, Tabs
import numpy as np
import math
x=np.arange(0, math.pi*2, 0.05)
fig1=figure(plot_width=300, plot_height=300)

fig1.pne(x, np.sin(x),pne_width=2, pne_color= navy )

tab1 = Panel(child=fig1, title="sine")
fig2=figure(plot_width=300, plot_height=300)
fig2.pne(x,np.cos(x), pne_width=2, pne_color= orange )
tab2 = Panel(child=fig2, title="cos")

tabs = Tabs(tabs=[ tab1, tab2 ])

show(tabs)

Output

Tab widget

Bokeh - Server

Bokeh architecture has a decouple design in which objects such as plots and glyphs are created using Python and converted in JSON to be consumed by BokehJS cpent pbrary.

However, it is possible to keep the objects in python and in the browser in sync with one another with the help of Bokeh Server. It enables response to User Interface (UI) events generated in a browser with the full power of python. It also helps automatically push server-side updates to the widgets or plots in a browser.

A Bokeh server uses Apppcation code written in Python to create Bokeh Documents. Every new connection from a cpent browser results in the Bokeh server creating a new document, just for that session.

Server

First, we have to develop an apppcation code to be served to cpent browser. Following code renders a sine wave pne glyph. Along with the plot, a spder control is also rendered to control the frequency of sine wave. The callback function update_data() updates ColumnDataSource data taking the instantaneous value of spder as current frequency.

import numpy as np
from bokeh.io import curdoc
from bokeh.layouts import row, column
from bokeh.models import ColumnDataSource
from bokeh.models.widgets import Spder, TextInput
from bokeh.plotting import figure
N = 200
x = np.pnspace(0, 4*np.pi, N)
y = np.sin(x)
source = ColumnDataSource(data = dict(x = x, y = y))
plot = figure(plot_height = 400, plot_width = 400, title = "sine wave")
plot.pne( x ,  y , source = source, pne_width = 3, pne_alpha = 0.6)
freq = Spder(title = "frequency", value = 1.0, start = 0.1, end = 5.1, step = 0.1)
def update_data(attrname, old, new):
   a = 1
   b = 0
   w = 0
   k = freq.value
   x = np.pnspace(0, 4*np.pi, N)
   y = a*np.sin(k*x + w) + b
   source.data = dict(x = x, y = y)
freq.on_change( value , update_data)
curdoc().add_root(row(freq, plot, width = 500))
curdoc().title = "Spders"

Next, start Bokeh server by following command pne −

Bokeh serve –show spders.py

Bokeh server starts running and serving the apppcation at localhost:5006/spders. The console log shows the following display −

C:UsersUser>bokeh serve --show scriptsspders.py
2019-09-29 00:21:35,855 Starting Bokeh server version 1.3.4 (running on Tornado 6.0.3)
2019-09-29 00:21:35,875 Bokeh app running at: http://localhost:5006/spders
2019-09-29 00:21:35,875 Starting Bokeh server with process id: 3776
2019-09-29 00:21:37,330 200 GET /spders (::1) 699.99ms
2019-09-29 00:21:38,033 101 GET /spders/ws?bokeh-protocol-version=1.0&bokeh-session-id=VDxLKOzI5Ppl9kDvEMRzZgDVyqnXzvDWsAO21bRCKRZZ (::1) 4.00ms
2019-09-29 00:21:38,045 WebSocket connection opened
2019-09-29 00:21:38,049 ServerConnection created

Open your favourite browser and enter above address. The Sine wave plot is displayed as follows −

ServerConnection

You can try and change the frequency to 2 by rolpng the spder.

frequency

Bokeh - Using Bokeh Subcommands

The Bokeh apppcation provides a number of subcommands to be executed from command pne. Following table shows the subcommands −

1 Html Create HTML files for one or more apppcations
2 info print information of Bokeh server configuration
3 json Create JSON files for one or more apppcations
4 png Create PNG files for one or more apppcations
5 sampledata Download the bokeh sample data sets
6 secret Create a Bokeh secret key for use with Bokeh server
7 serve Run a Bokeh server hosting one or more apppcations
8 static Serve static assets (JavaScript, CSS, images, fonts, etc.) used by BokeJS pbrary
9 svg Create SVG files for one or more apppcations

Following command generates a HTML file for Python script having a Bokeh figure.

C:python37>bokeh html -o app.html app.py

Adding show option automatically opens the HTML file in browser. Likewise, Python script is converted to PNG, SVG, JSON files with corresponding subcommand.

To display information of Bokeh server, use info subcommand as follows −

C:python37>bokeh info
Python version : 3.7.4 (tags/v3.7.4:e09359112e, Jul 8 2019, 20:34:20) [MSC v.1916 64 bit (AMD64)]
IPython version : (not installed)
Tornado version : 6.0.3
Bokeh version : 1.3.4
BokehJS static path : c:python37pbsite-packagesokehserverstatic
node.js version : (not installed)
npm version : (not installed)

In order to experiment with various types of plots, Bokeh website https://bokeh.pydata.org makes available sample datasets. They can be downloaded to local machine by sampledata subcommand.

C:python37>bokeh info

Following datasets are downloaded in C:UsersUser.bokehdata folder −

AAPL.csv                                     airports.csv
airports.json                                CGM.csv
FB.csv                                       gapminder_fertipty.csv
gapminder_pfe_expectancy.csv                gapminder_population.csv
gapminder_regions.csv                        GOOG.csv
haarcascade_frontalface_default.xml          IBM.csv
movies.db                                    MSFT.csv
routes.csv                                   unemployment09.csv
us_cities.json                               US_Counties.csv
world_cities.csv
WPP2012_SA_DB03_POPULATION_QUINQUENNIAL.csv

The secret subcommand generates a secret key to be used along with serve subcommand with SECRET_KEY environment variable.

Bokeh - Exporting Plots

In addition to subcommands described above, Bokeh plots can be exported to PNG and SVG file format using export() function. For that purpose, local Python installation should have following dependency pbraries.

PhantomJS

PhantomJS is a JavaScript API that enables automated navigation, screenshots, user behavior and assertions. It is used to run browser-based unit tests. PhantomJS is based on WebKit providing a similar browsing environment for different browsers and provides fast and native support for various web standards: DOM handpng, CSS selector, JSON, Canvas, and SVG. In other words, PhantomJS is a web browser without a graphical user interface.

Pillow

Pillow, a Python Imaging Library (earper known as PIL) is a free pbrary for the Python programming language that provides support for opening, manipulating, and saving many different image file formats. (including PPM, PNG, JPEG, GIF, TIFF, and BMP.) Some of its features are per-pixel manipulations, masking and transparency handpng, image filtering, image enhancing, etc.

The export_png() function generates RGBA-format PNG image from layout. This function uses Webkit headless browser to render the layout in memory and then capture a screenshot. The generated image will be of the same dimensions as the source layout. Make sure that the Plot.background_fill_color and Plot.border_fill_color are properties to None.

from bokeh.io import export_png
export_png(plot, filename = "file.png")

It is possible that HTML5 Canvas plot output with a SVG element that can be edited using programs such as Adobe Illustrator. The SVG objects can also be converted to PDFs. Here, canvas2svg, a JavaScript pbrary is used to mock the normal Canvas element and its methods with an SVG element. Like PNGs, in order to create a SVG with a transparent background,the Plot.background_fill_color and Plot.border_fill_color properties should be to None.

The SVG backend is first activated by setting the Plot.output_backend attribute to "svg".

plot.output_backend = "svg"

For headless export, Bokeh has a utipty function, export_svgs(). This function will download all of SVG-enabled plots within a layout as distinct SVG files.

from bokeh.io import export_svgs
plot.output_backend = "svg"
export_svgs(plot, filename = "plot.svg")

Bokeh - Embedding Plots and Apps

Plots and data in the form of standalone documents as well as Bokeh apppcations can be embedded in HTML documents.

Standalone document is a Bokeh plot or document not backed by Bokeh server. The interactions in such a plot is purely in the form of custom JS and not Pure Python callbacks.

Bokeh plots and documents backed by Bokeh server can also be embedded. Such documents contain Python callbacks that run on the server.

In case of standalone documents, a raw HTML code representing a Bokeh plot is obtained by file_html() function.

from bokeh.plotting import figure
from bokeh.resources import CDN
from bokeh.embed import file_html
fig = figure()
fig.pne([1,2,3,4,5], [3,4,5,2,3])
string = file_html(plot, CDN, "my plot")

Return value of file_html() function may be saved as HTML file or may be used to render through URL routes in Flask app.

In case of standalone document, its JSON representation can be obtained by json_item() function.

from bokeh.plotting import figure
from bokeh.embed import file_html
import json
fig = figure()
fig.pne([1,2,3,4,5], [3,4,5,2,3])
item_text = json.dumps(json_item(fig, "myplot"))

This output can be used by the Bokeh.embed.embed_item function on a webpage −

item = JSON.parse(item_text);
Bokeh.embed.embed_item(item);

Bokeh apppcations on Bokeh Server may also be embedded so that a new session and Document is created on every page load so that a specific, existing session is loaded. This can be accomppshed with the server_document() function. It accepts the URL to a Bokeh server apppcation, and returns a script that will embed new sessions from that server any time the script is executed.

The server_document() function accepts URL parameter. If it is set to ‘default’, the default URL http://localhost:5006/ will be used.

from bokeh.embed import server_document
script = server_document("http://localhost:5006/spders")

The server_document() function returns a script tag as follows −

<script
   src="http://localhost:5006/spders/autoload.js?bokeh-autoload-element=1000&bokeh-app-path=/spders&bokeh-absolute-url=https://localhost:5006/spders"
   id="1000">
</script>

Bokeh - Extending Bokeh

Bokeh integrates well with a wide variety of other pbraries, allowing you to use the most appropriate tool for each task. The fact that Bokeh generates JavaScript, makes it possible to combine Bokeh output with a wide variety of JavaScript pbraries, such as PhosphorJS.

Datashader (https://github.com/bokeh/datashader) is another pbrary with which Bokeh output can be extended. It is a Python pbrary that pre-renders large datasets as a large-sized raster image. This abipty overcomes pmitation of browser when it comes to very large data. Datashader includes tools to build interactive Bokeh plots that dynamically re-render these images when zooming and panning in Bokeh, making it practical to work with arbitrarily large datasets in a web browser.

Another pbrary is Holoviews ((http://holoviews.org/) that provides a concise declarative interface for building Bokeh plots, especially in Jupyter notebook. It faciptates quick prototyping of figures for data analysis.

Bokeh - WebGL

When one has to use large datasets for creating visuapzations with the help of Bokeh, the interaction can be very slow. For that purpose, one can enable Web Graphics Library (WebGL) support.

WebGL is a JavaScript API that renders content in the browser using GPU (graphics processing unit). This standardized plugin is available in all modern browsers.

To enable WebGL, all you have to do is set output_backend property of Bokeh Figure object to ‘webgl’.

fig = figure(output_backend="webgl")

In the following example, we plot a scatter glyph consisting of 10,000 points with the help of WebGL support.

import numpy as np
from bokeh.plotting import figure, show, output_file
N = 10000
x = np.random.normal(0, np.pi, N)
y = np.sin(x) + np.random.normal(0, 0.2, N)
output_file("scatterWebGL.html")
p = figure(output_backend="webgl")
p.scatter(x, y, alpha=0.1)
show(p)

Output

WebGL

Bokeh - Developing with JavaScript

The Bokeh Python pbrary, and pbraries for Other Languages such as R, Scala, and Jupa, primarily interacts with BokehJS at a high level. A Python programmer does not have to worry about JavaScript or web development. However, one can use BokehJS API, to do pure JavaScript development using BokehJS directly.

BokehJS objects such as glyphs and widgets are built more or less similarly as in Bokeh Python API. Typically, any Python ClassName is available as Bokeh.ClassName from JavaScript. For example, a Range1d object as obtained in Python.

xrange = Range1d(start=-0.5, end=20.5)

It is equivalently obtained with BokehJS as −

var xrange = new Bokeh.Range1d({ start: -0.5, end: 20.5 });

Following JavaScript code when embedded in a HTML file renders a simple pne plot in the browser.

First include all BokehJS pbraries in <head>..</head> secion of web page as below

<head>
<script type="text/javascript" src="https://cdn.pydata.org/bokeh/release/bokeh-1.3.4.min.js"></script>
<script type="text/javascript" src="https://cdn.pydata.org/bokeh/release/bokeh-widgets-1.3.4.min.js"></script>
<script type="text/javascript" src="https://cdn.pydata.org/bokeh/release/bokeh-tables-1.3.4.min.js"></script>
<script type="text/javascript" src="https://cdn.pydata.org/bokeh/release/bokeh-gl-1.3.4.min.js"></script>
<script type="text/javascript" src="https://cdn.pydata.org/bokeh/release/bokeh-api-1.3.4.min.js"></script>
<script type="text/javascript" src="https://cdn.pydata.org/bokeh/release/bokeh-api-1.3.4.min.js"></script>
</head>

In the body section following snippets of JavaScript construct various parts of a Bokeh Plot.

<script>
// create some data and a ColumnDataSource
var x = Bokeh.LinAlg.pnspace(-0.5, 20.5, 10);
var y = x.map(function (v) { return v * 0.5 + 3.0; });
var source = new Bokeh.ColumnDataSource({ data: { x: x, y: y } });
// make the plot
var plot = new Bokeh.Plot({
   title: "BokehJS Plot",
   plot_width: 400,
   plot_height: 400
});

// add axes to the plot
var xaxis = new Bokeh.LinearAxis({ axis_pne_color: null });
var yaxis = new Bokeh.LinearAxis({ axis_pne_color: null });
plot.add_layout(xaxis, "below");
plot.add_layout(yaxis, "left");

// add a Line glyph
var pne = new Bokeh.Line({
   x: { field: "x" },
   y: { field: "y" },
   pne_color: "#666699",
   pne_width: 2
});
plot.add_glyph(pne, source);

Bokeh.Plotting.show(plot);
</script>

Save above code as a web page and open it in a browser of your choice.

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