An interface to communicate with Jupyter kernels in Emacs.
- What does this package do?
- How do I install this package?
- Related packages
- How do I use the built-in frontends?
- Provides REPL and
org-mode
source block frontends to Jupyter kernels. - Kernel interactions integrated with Emacs’s built-in features. For
example
- Inspecting a piece of code under
point
will display the information for that symbol in the*Help*
buffer. You can re-visit inspection requests made to the kernel by callinghelp-go-back
orhelp-go-forward
while in the*Help*
buffer. - Uses the
completion-at-point
interface for code completion. - Kernel requests for user input entered through the minibuffer.
- You can search through REPL history using
isearch
.
- Inspecting a piece of code under
NOTE: This package relies on the emacs-zmq
package which means your
Emacs needs to have been built with module support. See the README of
that package for more information.
You can install this package with any package manager that allows you to install MELPA packages. For Emacs’s built-in package manager:
- Ensure MELPA is in
package-archives
(add-to-list 'package-archives '("melpa" . "https://melpa.org/packages/"))
- Ensure the latest versions of MELPA packages are available
M-x package-refresh-contents RET
- Install Jupyter
M-x package-install RET jupyter RET
For a manual installation you can add the repository directory to your
load-path
and ensure the following dependencies are installed:
- markdown-mode (optional)
- https://jblevins.org/projects/markdown-mode/
- company-mode (optional)
- http://company-mode.github.io/
- emacs-websocket
- https://github.com/ahyatt/emacs-websocket
- simple-httpd
- https://github.com/skeeto/emacs-web-server
- zmq
- http://github.com/nnicandro/emacs-zmq
(add-to-list 'load-path "~/path/to/jupyter")
(require 'jupyter)
There is limited support for interacting with Jupyter widgets through an external browser. In this case, Emacs acts as a relay for passing messages between the kernel and the browser.
To try it out, install node
(https://nodejs.org/en/) then run the
following shell command from the top-level directory of this project.
make widgets
After, launch Emacs, connect to a kernel (e.g. through a REPL), and run some code that creates a widget.
You must have Cask installed to be able to run the tests. Once Cask is installed, in the top level directory of this project run the following from the command line
# Install all development dependencies via Cask
make dev
Then, to run the tests
# Run the whole set of tests
make test
# Run tests tagged with org
make test TAGS=org
# Run tests tagged with org and babel
make test TAGS=org,babel
# Run tests whose name match a pattern
make test PATTERN=font-lock
The org-mode
source block frontend in emacs-jupyter
is similar to what is
offered by ob-ipython (and also the scimax version).
ein is a complete Jupyter notebook interface in Emacs with many powerful
features for Python kernels. There is some overlap in the features provided by
emacs-jupyter
and ein
, but I have never used ein
so I cannot speak very
much about any similarities/differences.
M-x jupyter-run-repl
launches a new local kernel and displays a REPL
buffer.
M-x jupyter-connect-repl
connects to an existing kernel using the
kernel’s connection file, which is supplied by the user, and displays
a REPL buffer.
The REPL supports some of the rich output that a kernel may send to a client, e.g. images, LaTeX, and HTML.
Below is a table of the supported output mimetypes and their dependencies. If a dependency is not available for a particular mimetype, a mimetype of lower priority gets displayed instead.
For widgets, before attempting to open one, you also need to run the
shell command make widgets
in the top-level directory of this project
to build some JavaScript files.
Mimetype | Dependencies |
---|---|
application/vnd.jupyter.widget-view+json | websocket, simple-httpd |
text/html | Emacs built with libxml2 |
text/markdown | markdown-mode |
text/latex | org-mode |
image/svg+xml | Emacs built with librsvg2 |
image/png | none |
text/plain | none |
To inspect the code around point
press M-i
.
Completion is implemented through the completion-at-point
interface
and should just work.
In addition to completing symbols in the REPL buffer, completion also
works in buffers associated with a REPL. For org-mode
users, there is
even completion in the org-mode
buffer when editing the contents of a
Jupyter source code block.
To navigate the REPL history: M-n
and M-p
.
To search the REPL history: C-s
and C-s C-r
.
M-x jupyter-repl-associate-buffer
sets the jupyter-current-client
of
the current buffer to an existing REPL client and
enables jupyter-repl-interaction-mode
, allowing you to, for example,
send the current line for evaluation by the client’s kernel.
When jupyter-repl-interaction-mode
is enabled, the following
keybindings are available
Key binding | Command |
---|---|
C-M-x | jupyter-eval-defun |
M-i | jupyter-inspect-at-point |
C-c C-b | jupyter-eval-buffer |
C-c C-c | jupyter-eval-line-or-region |
C-c C-i | jupyter-repl-interrupt-kernel |
C-c C-r | jupyter-repl-restart-kernel |
C-c C-s | jupyter-repl-scratch-buffer |
C-c C-o | jupyter-eval-remove-overlays |
C-c M-: | jupyter-eval-string |
If emacsclient
is set as the EDITOR
and evaluated code opens a file in
a major-mode
compatible with the client that sent the code, the opened
file will automatically be associated with the client and have
jupyter-repl-interaction-mode
enabled.
This feature probably wont work correctly when there are multiple
competing clients sending requests to their underlying kernels that
want to open files or if the underlying kernel takes longer
than jupyter-long-timeout
seconds to open a file.
See jupyter-server-mode-set-client
for more details.
A variable that determines the maximum number of lines a REPL buffer can have before being truncated.
A variable that determines whether to allow insertion of newlines in a REPL cell when a kernel is busy or not. See the variable documentation for more details.
A variable that determines whether code evaluated with
the jupyter-eval-*
commands gets copied over to a REPL input cell or
not. You can set this variable to t
if you prefer having the history
of all evaluated code visible in the REPL.
To enable support for Jupyter based source code blocks, add jupyter
to org-babel-load-languages
. Ensure the jupyter
entry is added last
since loading ob-jupyter
depends on the value of variables such
as org-src-lang-modes
and org-babel-tangle-lang-exts
.
(org-babel-do-load-languages
'org-babel-load-languages
'((emacs-lisp . t)
(julia . t)
(python . t)
(jupyter . t)))
After loading, source code blocks with names like jupyter-LANG
will be
available for use. LANG
can be any one of the kernel languages found
on your system. See jupyter-available-kernelspecs
.
- The
:session
parameter is required for all Jupyter based source code blocks.#+BEGIN_SRC jupyter-python :session py x = 'foo' y = 'bar' x + ' ' + y #+END_SRC
- By default, source blocks are executed synchronously. To execute a
source block asynchronously set the
:async
parameter toyes
:#+BEGIN_SRC jupyter-python :session py :async yes x = 'foo' y = 'bar' x + ' ' + y #+END_SRC
- To change the kernel, set the
:kernel
parameter.#+BEGIN_SRC jupyter-python :session py :async yes :kernel python2 x = 'foo' y = 'bar' x + ' ' + y #+END_SRC
Note, the same session name can be used for different values of
:kernel
since the underlying REPL buffer’s name is based on both:session
and:kernel
. - Any of the default parameters for a language can be changed by
setting
org-babel-default-header-args:jupyter-LANG
to an appropriate value. For example to change the defaults for thejulia
kernel, you can setorg-babel-default-header-args:jupyter-julia
to something like(setq org-babel-default-header-args:jupyter-julia '((:async . "yes") (:session . "jl") (:kernel . "julia-1.0")))
Some kernelspecs use spaces in the name of the kernel language. Those
get replaced by dashes in the language name you need to use for the
corresponding source blocks, e.g. Wolfram Language
has the source
block language jupyter-Wolfram-Language
.
If you have ob-async
installed and are getting errors when your source
block specifies the :async
header argument, try putting something like
the following in your configuration:
(setq ob-async-no-async-languages-alist '("jupyter-python" "jupyter-julia"))
See ob-async-no-async-languages-alist for more details.
If both ob-ipython
and this package are installed, you may experience
issues such as this one, causing Search failed
errors. To avoid such
errors, remove ipython
from org-babel-do-load-languages
and restart
your Emacs.
Instead of having to specify jupyter-LANG
as a source block name, you
can have LANG
source blocks use the Jupyter machinery. To do so,
place a call to org-babel-jupyter-override-src-block
somewhere in your
config (after the call to org-babel-do-load-languages
).
(org-babel-jupyter-override-src-block "python")
After calling the above function, all python
source blocks are effectively
aliases of jupyter-python
source blocks and the variable
org-babel-default-header-args:python
will be set to the value of
org-babel-default-header-args:jupyter-python
.
Note, org-babel-default-header-args:python
will not be an alias
of org-babel-default-header-args:jupyter-python
, the value of the
former is merely set to the value of the latter after
calling org-babel-jupyter-override-src-block
.
You can restore the original behavior by
calling org-babel-jupyter-restore-src-block
.
(org-babel-jupyter-restore-src-block "python")
The supported display mimetypes ordered by priority are:
- text/org
- image/svg+xml, image/jpeg, image/png
- text/html
- text/markdown
- text/latex
- text/plain
There are some cases where the normal result insertion mechanism may
not be wanted. To control result insertion somewhat, use the :results
header argument:
- Insert unwrapped LaTeX
- Normally LaTeX results are wrapped in a
BEGIN_EXPORT
block, in order to insert LaTeX unwrapped, specify:results raw
. - Suppress table creation
- Whenever a result can be converted into an
org-mode
table, e.g. when it look like[1, 2 , 3]
, it is automatically converted into a table. To suppress this behavior you can specify:results scalar
.
Whenever an image result is returned, a random image file name is
generated and the image is written
to org-babel-jupyter-resource-directory
. To specify your own file name
for the image, set the :file
header argument.
The priority of mimetypes used to display results can be overwritten using the
:display
option. If instead of displaying HTML results we’d wish to display
plain text, the argument :display text/plain text/html
would prioritize plain
text results over html ones. The following example displays plain text instead
of HTML:
#+BEGIN_SRC jupyter-python :session py :display plain
import pandas as pd
data = [[1, 2], [3, 4]]
pd.DataFrame(data, columns=["Foo", "Bar"])
#+END_SRC
For images sent by the kernel, if no :file
parameter is provided to the code
block, a file name is automatically generated based on the image data and the
image is written to file in org-babel-jupyter-resource-directory
. This is
great for quickly generating throw-away plots while you are working on your
code. Once you are happy with your results you can specify the :file
parameter to fix the file name.
This variable is similar to org-preview-latex-image-directory
but solely for
any files created when Jupyter code blocks are run, e.g. automatically
generated image file names.
Whenever you run a code block multiple times and replace its results, before
the results are replaced, any generated files will be deleted to reduce the
clutter in org-babel-jupyter-resource-directory
.
By default html, markdown, and latex results are wrapped in a BEGIN_EXPORT
block. If the header argument :pandoc t
is set, they are instead
converted to org-mode format with pandoc. You can control which outputs get
converted with the custom variable jupyter-org-pandoc-convertable
.
When editing a Jupyter code block’s contents, i.e. by pressing C-c '
when at
a code block, jupyter-repl-interaction-mode
is automatically enabled in the
edit buffer and the buffer will be associated with the REPL session of the code
block (see jupyter-repl-associate-buffer
).
You may also bind the command org-babel-jupyter-scratch-buffer
to an
appropriate key in org-mode
to display a scratch buffer in the code block’s
major-mode
and connected to the code block’s session.
To connect to an existing kernel, pass the kernel’s connection file as the
value of the :session
parameter. The name of the file must have a .json
suffix for this to work.
If the connection file is a remote file name, i.e. has a prefix like
/method:host:
, the kernel’s ports are assumed to live on host
. Before
attempting to connect to the kernel, ssh
tunnels for the connection are
created. So if you had a remote kernel on a host named ec2
whose connection
file is /run/user/1000/jupyter/kernel-julia-0.6.json
on that host, you could
specify the :session
like
#+BEGIN_SRC jupyter-julia :session /ssh:ec2:/run/user/1000/jupyter/kernel-julia-0.6.json
...
#+END_SRC
Note, the kernel on the remote host needs to have the ZMQ socket ports exposed. This means that starting a kernel using
jupyter notebook --no-browser
currently doesn’t work since the notebook server does not allow communication with a kernel using ZMQ sockets. You will have to use the connection file created from using something like
jupyter kernel --kernel=python
Currently there is no password handling, so if your ssh
connection requires a
password I suggest you instead use key-based authentication. Or if you are
connecting to a server using a pem
file add something like
Host ec2
User <user>
HostName <host>
IdentityFile <identity>.pem
to your ~/.ssh/config
file.
If :session
is a remote file name that doesn’t end in .json
, e.g.
/ssh:ec2:jl
, then a kernel on the remote host /ssh:ec2:
is started using
the jupyter kernel
command on the host. The local part of the session name
serves to distinguish different remote sessions on the same host.
If :session
is a TRAMP file name like /jpy:localhost#8888:NAME
it is
interpreted as corresponding to a connection to a kernel through a Jupyter
notebook server located at http://localhost:8888
.
If NAME
is a kernel ID corresponding to an existing kernel on a server,
e.g. /jpy::161b2318-180c-497a-b4bf-de76176061d9
, then a connection to an
existing kernel with the corresponding ID will be made. Otherwise, a new kernel
will be launched on the server and NAME
will be used as an identifier for the
session.
When a new kernel is launched, NAME
will also be associated with the kernel’s
ID, see jupyter-server-kernel-names
. This is useful to distinguish Org
mode :session
kernels from other ones in the buffer shown
by jupyter-server-list-kernels
.
When connecting to an existing kernel, i.e. when NAME
is the ID of a kernel,
the :kernel
header argument must match the name of the kernel’s kernelspec.
To connect to a kernel behind an HTTPS
connection, use a TRAMP file name that
looks like /jpys:...
instead.
One significant difference between Jupyter code blocks and regular org-mode
code blocks is that the underlying Jupyter kernel can request that the client
display extra data in addition to output or the result of a code block. See
display_data messages.
To account for this, Jupyter code blocks do not go through the normal
org-mode
result insertion mechanism (see org-babel-insert-result
). The
downside of this is that, compared to normal code blocks, only a small subset
of the header arguments common to all code blocks are supported. The upside is
that all forms of results produced by a kernel can be inserted into the buffer
similar to a Jupyter notebook.
The implementation of org-mode
code blocks is really meant to handle either
capturing the standard output or the result of a code block. When using
Jupyter code blocks, if the kernel produces output or asks to display extra
information, the results are appended to a :RESULTS:
drawer.
A minor mode that enables completion and custom keybindings when point
is
inside a Jupyter code block. This mode is enabled by default in org-mode
buffers, but only has an effect when point
is inside a Jupyter code block.
You can define new keybindings that are enabled when point
is inside a
Jupyter code block by using the function jupyter-org-define-key
. These
bindings are added to jupyter-org-interaction-mode-map
and are only active
when jupyter-org-interaction-mode
is enabled.
By default the following keybindings from jupyter-repl-interaction-mode
are
available when jupyter-org-interaction-mode
is enabled
Key binding | Command |
---|---|
C-M-x | jupyter-eval-defun |
M-i | jupyter-inspect-at-point |
C-x C-e | jupyter-eval-line-or-region |
C-c C-i | jupyter-repl-interrupt-kernel |
C-c C-r | jupyter-repl-restart-kernel |
The main entry point for working with a kernel server is the
jupyter-server-list-kernels
command which shows a list of all live kernels
from the server URL that you provide when first calling the command. Any
subsequent calls to the command will use the same URL as the first call. To
change server URLs give a prefix argument, C-u M-x jupyter-server-list-kernels
. This
will then set the current server URL for future calls to the one you provide.
See the jupyter-current-server
command for more details.
From the buffer shown by jupyter-server-list-kernels
you can launch new kernels
(C-RET
), connect a REPL to an existing kernel (RET
), interrupt a kernel
(C-c TAB
), kill a kernel (C-c C-d
or d
), refresh the list of kernels (g
) etc.
See the jupyter-server-kernel-list-mode
for all the available key bindings.
Note, the default-directory
of the jupyter-server-kernel-list-mode
buffer
will be the root directory of the kernel server (so that dired-jump
will show
a dired
listing of the directory). See the section on TRAMP integration
below.
From the jupyter-server-list-kernels
buffer one can also name (or rename) a
kernel (R
) so that it has an identifier other than its ID. Naming a kernel adds
the name to the jupyter-server-kernel-names
global variable in a form suitable
for persisting across Emacs sessions. See its documentation for more details
about persisting its value.
There is also integration with the Jupyter notebook contents API in the form of
a TRAMP backend. This means that reading/writing the contents of directories
the notebook server has access to can be done using normal Emacs file
operations using file names with TRAMP syntax. Two new TRAMP file name methods
are defined, jpy
for HTTP connections and jpys
for HTTPS connections. So
suppose you have a local notebook server at http://localhost:8888, then to
access its directory contents you can type
M-x dired RET /jpy:localhost#8888:/
Note localhost
is the default host and 8888
is the default port so /jpy::
is equivalent to /jpy:localhost#8888:
. You can change the defaults by
modifying the jpy
or jpys
methods in the variable tramp-methods
and
tramp-default-host-alist
.
Authentication method used for new notebook server connections. By default, when connecting to a new notebook server you will be asked if either a password or a token should be used for authentication. If you only use tokens for authentication you can change this variable to avoid being asked on every new connection.
When non-nil, display the text/plain
representation of evaluation
results inline using overlays. All other representations are
displayed in the usual way. This only works with the jupyter-eval-*
commands like jupyter-eval-line-or-region
.
You can control the appearance of the overlay,
see jupyter-eval-overlay-prefix
and the jupyter-eval-overlay
face.
To clear all overlays from the buffer,
bind jupyter-eval-remove-overlays
to some key. Its bound to C-c C-o
when jupyter-repl-interaction-mode
is enabled. Individual overlays
are removed whenever the text in the region that was evaluated is
modified.
For multi-line overlays you can fold/unfold the overlay by
pressing S-RET
when point
is inside the region of code that caused the
overlay to be created. See jupyter-eval-overlay-keymap
.
If the number of lines of an evaluation result is smaller than this
variable, the function stored
in jupyter-eval-short-result-display-function
is used to display a
result.