zulip/docs/production/security-model.md

243 lines
12 KiB
Markdown

# Security Model
This section attempts to document the Zulip security model. Since
this is new documentation, it likely does not cover every issue; if
there are details you're curious about, please feel free to ask
questions on the Zulip development mailing list (or if you think
you've found a security bug, please report it to
zulip-security@googlegroups.com so we can do a responsible security
announcement).
## Secure your Zulip server like your email server
* It's reasonable to think about security for a Zulip server like you
do security for a team email server -- only trusted administrators
within an organization should have shell access to the server.
In particular, anyone with root access to a Zulip application server
or Zulip database server, or with access to the `zulip` user on a
Zulip application server, has complete control over the Zulip
installation and all of its data (so they can read messages, modify
history, etc.). It would be difficult or impossible to avoid this,
because the server needs access to the data to support features
expected of a group chat system like the ability to search the
entire message history, and thus someone with control over the
server has access to that data as well.
## Encryption and Authentication
* Traffic between clients (web, desktop and mobile) and the Zulip is
encrypted using HTTPS. By default, all Zulip services talk to each
other either via a localhost connection or using an encrypted SSL
connection.
* Zulip requires CSRF tokens in all interactions with the web API to
prevent CSRF attacks.
* The preferred way to login to Zulip is using an SSO solution like
Google Auth, LDAP, or similar, but Zulip also supports password
authentication. See
[the authentication methods documentation](../production/authentication-methods.html)
for details on Zulip's available authentication methods.
### Passwords
Zulip stores user passwords using the standard PBKDF2 algorithm.
When the user is choosing a password, Zulip checks the password's
strength using the popular [zxcvbn][zxcvbn] library. Weak passwords
are rejected, and strong passwords encouraged. The minimum password
strength allowed is controlled by two settings in
`/etc/zulip/settings.py`:
* `PASSWORD_MIN_LENGTH`: The minimum acceptable length, in characters.
Shorter passwords are rejected even if they pass the `zxcvbn` test
controlled by `PASSWORD_MIN_GUESSES`.
* `PASSWORD_MIN_GUESSES`: The minimum acceptable strength of the
password, in terms of the estimated number of passwords an attacker
is likely to guess before trying this one. If the user attempts to
set a password that `zxcvbn` estimates to be guessable in less than
`PASSWORD_MIN_GUESSES`, then Zulip rejects the password.
By default, `PASSWORD_MIN_GUESSES` is 10000. This provides
significant protection against online attacks, while limiting the
burden imposed on users choosing a password.
<!--- Why 10000? See /production/password-strength.md. -->
Estimating the guessability of a password is a complex problem and
impossible to efficiently do perfectly. For background or when
considering an alternate value for this setting, the article
["Passwords and the Evolution of Imperfect Authentication"][BHOS15]
is recommended. The [2016 zxcvbn paper][zxcvbn-paper] adds useful
information about the performance of zxcvbn, and [a large 2012 study
of Yahoo users][Bon12] is informative about the strength of the
passwords users choose.
<!---
If the BHOS15 link ever goes dead: it's reference 30 of the zxcvbn
paper, aka https://dl.acm.org/citation.cfm?id=2699390 , in the
_Communications of the ACM_ aka CACM. (But the ACM has it paywalled.)
.
Hooray for USENIX and IEEE: the other papers' canonical links are
not paywalled. The Yahoo study is reference 5 in BHOS15.
-->
[zxcvbn]: https://github.com/dropbox/zxcvbn
[BHOS15]: http://www.cl.cam.ac.uk/~fms27/papers/2015-BonneauHerOorSta-passwords.pdf
[zxcvbn-paper]: https://www.usenix.org/system/files/conference/usenixsecurity16/sec16_paper_wheeler.pdf
[Bon12]: http://ieeexplore.ieee.org/document/6234435/
## Messages and History
* Zulip message content is rendered using a specialized Markdown
parser which escapes content to protect against cross-site scripting
attacks.
* Zulip supports both public streams and private ("invite-only")
streams. Any Zulip user can join any public stream in the realm,
and can view the complete message history of any public stream
without joining the stream.
* A private ("invite-only") stream is hidden from users who are not
subscribed to the stream. Users who are not members of a private
stream cannot read messages on the stream, send messages to the
stream, or join the stream, even if they are a Zulip realm
administrator. Users can join private streams only when they are
invited. However, any member of a private stream can invite other
users to the stream. When a new user joins a private stream, they
can see future messages sent to the stream, but they do not receive
access to the stream's message history.
* Zulip supports editing the content and topics of messages that have
already been sent. As a general philosophy, our policies provide
hard limits on the ways in which message content can be changed or
undone. In contrast, our policies around message topics favor
usefulness (e.g. for conversational organization) over faithfulness
to the original.
The message editing policy can be configured on the /#organization
page. There are three configurations provided out of the box: (i)
users cannot edit messages at all, (ii) users can edit any message
they have sent, and (iii) users can edit the content of any message
they have sent in the last N minutes, and the topic of any message
they have sent. In (ii) and (iii), topic edits can also be
propagated to other messages with the same original topic, even if
those messages were sent by other users. The default setting is
(iii), with N = 10.
In addition, and regardless of the configuration above, messages
with no topic can always be edited to have a topic, by anyone in the
organization, and the topic of any message can also always be edited
by a realm administrator.
Also note that while edited messages are synced immediately to open
browser windows, editing messages is not a safe way to redact secret
content (e.g. a password) shared unintentionally. Other users may
have seen and saved the content of the original message, or have an
integration (e.g. push notifications) forwarding all messages they
receive to another service. Zulip stores the edit history of
messages, but it may or may not be available to clients, depending
on an organization-level setting.
## Users and Bots
* There are three types of users in a Zulip realm: Administrators,
normal users, and bots. Administrators have the ability to
deactivate and reactivate other human and bot users, delete streams,
add/remove administrator privileges, as well as change configuration
for the overall realm (e.g. whether an invitation is required to
join the realm). Being a Zulip administrator does not provide the
ability to interact with other users' private messages or the
messages sent to private streams to which the administrator is not
subscribed. However, a Zulip administrator subscribed to a stream
can toggle whether that stream is public or private. Also, Zulip
realm administrators have administrative access to the API keys of
all bots in the realm, so a Zulip administrator may be able to
access messages sent to private streams that have bots subscribed,
by using the bot's credentials.
In the future, Zulip's security model may change to allow realm
administrators to access private messages (e.g. to support auditing
functionality).
* Every Zulip user has an API key, available on the settings page.
This API key can be used to do essentially everything the user can
do; for that reason, users should keep their API key safe. Users
can rotate their own API key if it is accidentally compromised.
* To properly remove a user's access to a Zulip team, it does not
suffice to change their password or deactivate their account in the
SSO system, since neither of those prevents authenticating with the
user's API key or those of bots the user has created. Instead, you
should deactivate the user's account in the "Organization settings"
interface (`/#organization`); this will automatically also
deactivate any bots the user had created.
* The Zulip mobile apps authenticate to the server by sending the
user's password and retrieving the user's API key; the apps then use
the API key to authenticate all future interactions with the site.
Thus, if a user's phone is lost, in addition to changing passwords,
you should rotate the user's Zulip API key.
* Zulip bots are used for integrations. A Zulip bot can do everything
a normal user in the realm can do including reading other, with a
few exceptions (e.g. a bot cannot login to the web application or
create other bots). In particular, with the API key for a Zulip
bot, one can read any message sent to a public stream in that bot's
realm. A likely future feature for Zulip is [limited bots that can
only send messages](https://github.com/zulip/zulip/issues/373).
* Certain Zulip bots can be marked as "API super users"; these special
bots have the ability to send messages that appear to have been sent
by another user (an important feature for implementing integrations
like the Jabber, IRC, and Zephyr mirrors). They also have the
ability to see the names of all streams (including private streams).
They can only be created on the command line (with `manage.py
knight --permission=api_super_user`).
## User-uploaded content
* Zulip supports user-uploaded files; ideally they should be hosted
from a separate domain from the main Zulip server to protect against
various same-domain attacks (e.g. zulip-user-content.example.com)
using the S3 integration.
The URLs of user-uploaded files are secret; if you are using the
"local file upload" integration, anyone with the URL of an uploaded
file can access the file. This means the local uploads integration
is vulnerable to a subtle attack where if a user clicks on a link in
a secret .PDF or .HTML file that had been uploaded to Zulip, access
to the file might be leaked to the other server via the Referrer
header (see [the "Uploads world readable" issue on
GitHub](https://github.com/zulip/zulip/issues/320)).
The Zulip S3 file upload integration is relatively safe against that
attack, because the URLs of files presented to users don't host the
content. Instead, the S3 integration checks the user has a valid
Zulip session in the relevant realm, and if so then redirects the
browser to a one-time S3 URL that expires a short time later.
Keeping the URL secret is still important to avoid other users in
the Zulip realm from being able to access the file.
* Zulip supports using the Camo image proxy to proxy content like
inline image previews that can be inserted into the Zulip message
feed by other users over HTTPS.
* By default, Zulip will provide image previews inline in the body of
messages when a message contains a link to an image. You can
control this using the `INLINE_IMAGE_PREVIEW` setting.
## Final notes and security response
If you find some aspect of Zulip that seems inconsistent with this
security model, please report it to zulip-security@googlegroups.com so
that we can investigate and coordinate an appropriate security release
if needed.
Zulip security announcements will be sent to
zulip-announce@googlegroups.com, so you should subscribe if you are
running Zulip in production.